Stabilized alpha-galactosidase and uses thereof

ABSTRACT

Multimeric protein structures comprising at least two alpha-galactosidase monomers being covalently linked to one another via a linking moiety are disclosed herein, as well a process for preparing same, and methods of treating Fabry disease via administration of a multimeric protein structure. The disclosed multimeric protein structures exhibit an improved performance, in terms of enhanced activity and/or a longer lasting activity under both lysosomal conditions and in a serum environment.

RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 15/636,753, filed on Jun. 29, 2017; which is a continuation of U.S. patent application Ser. No. 14/936,720, filed on Nov. 10, 2015, now U.S. Pat. No. 9,708,595, issued on Jul. 18, 2017; which is a continuation of U.S. patent application Ser. No. 13/582,482, filed on Sep. 4, 2012, now U.S. Pat. No. 9,194,011, issued on Nov. 24, 2015; which is a National Phase of PCT Patent Application No. PCT/IL2011/000209 having International Filing Date of Mar. 2, 2011; which claims the benefit of priority of U.S. Provisional Patent Application Nos. 61/309,487, filed on Mar. 2, 2010; 61/434,499, filed on Jan. 20, 2011 and 61/434,503, filed on Jan. 20, 2011; and which is also a Continuation-in-Part (CIP) of PCT Patent Application No. PCT/IL2010/000956 having International Filing Date of Nov. 17, 2010.

PCT Patent Application No. PCT/IL2010/000956 claims the benefit of priority of U.S. Provisional Patent Application No. 61/261,787, filed on Nov. 17, 2009. The contents of each the above applications are all incorporated by reference as if fully set for the herein in their entirety.

SEQUENCE LISTING STATEMENT

The ASCII file, entitled “131219-00107_Sequence_Listing.txt”, created on Jun. 23, 2017, comprising 79,252 bytes, submitted concurrently with the filing of this application is incorporated herein by reference.

FIELD AND BACKGROUND OF THE INVENTION

The present invention, in some embodiments thereof, relates to novel multimeric protein structures and, more particularly, but not exclusively, to multimeric protein structures of α-galactosidase and to uses thereof in treating Fabry disease.

The lysosomal enzyme α-galactosidase-A (α-GAL or α-Gal A; EC 3.2.1.22) catalyzes the removal of galactose from oligosaccharides, glycoproteins and glycolipids during the catabolism of macromolecules. Deficiencies in lysosomal enzymes lead to the accumulation of their substrates in the tissues, conditions known as lysosomal storage diseases. In humans, the absence of functional α-galactosidase-A leads to the accumulation of glycolipids containing terminal α-galactose residues (primarily globotriaosylceramide, which is also referred to as “ceramide trihexoside”, “CTH” or “Gb₃”) in the tissues, leading to Fabry disease. Fabry disease is an X-linked recessive disorder, first described in 1898, characterized by chronic pain, ocular opacities, liver and kidney impairment, skin lesions, vascular deterioration and/or cardiac deficiencies. Recombinant human α-galactosidase-A has the ability to restore enzyme function in patients, and enzyme replacement therapy (ERT) using α-GAL was approved in the United States in 2003 as a treatment for Fabry disease. α-GAL became the second recombinant protein approved for the treatment of a lysosomal storage disorder after β-glucosidase, a treatment for Gaucher disease.

Endogenous and recombinant α-GALs catalyze the hydrolysis of terminal galactosylated glycolipids in the lysosomes of cells of organs such as the liver, kidneys, spleen, heart, etc. This natural action site is characterized by its low pH, reaching as low as 4.5. Lysosomal enzymes, including α-GAL, are hence designed to exert their maximal activity at these low pH levels.

Current Fabry ERT treatments are based on mammalian-cell derived recombinant α-GAL which is considered to be a limited efficiency treatment. These treatments only decelerate the progress of the disease but are not able to stop its progress and do not offer a true and complete solution. Furthermore, in some cases, ERT with commercial recombinant α-GALs must be ceased due to development of an immunogenic response to the treatment and in some cases the treatment cannot be initiated in light of immunogenicity problems.

X-ray structure analysis reveals that human α-GAL is a homodimeric glycoprotein with each monomer composed of two domains, a (β/α)₈ domain containing the active site and a C-terminal domain containing eight antiparallel β strands on two sheets in a β sandwich [Garman & Garboczi, J Mol Biol 2004, 337:319-3351]. The two monomers are arranged in a head-to-tail assembly and the dimerization is non-covalent. The two monomers pack with an interface that extends the 75 Å width of the dimer and buries 2200 Å² of surface area. In the dimer interface, 30 residues from each monomer contribute to the interface. The two active sites of the dimer are separated by approximately 50 Å.

The crystal structure of α-Gal was solved for a non-liganded protein as well as for a galactose-liganded protein. These two structures exhibit little change between the liganded and non-liganded structures. Nevertheless, the use of galactose instead of the natural substrate, globotriaosylceramide (Gb₃), the latter characterized by long lipidic chains able to interact with the hydrophobic domain of one monomer while the terminal galactose interacts with the active site of the second monomer, may not lead to evidence of active site cooperativity. Furthermore, biochemical evidence does suggest such cooperativity, exemplifying the importance of the homodimeric quaternary structure [Bishop & Desnick, J Biol Chem 1981, 256:1307-13161]. Thus, the kinetic properties of human α-Gal were studied and cooperativity between the monomers of the homodimeric enzyme, each with an interacting catalytic site, was shown. It was therefore suggested that enzymatic activity and stability may be dependent on dimerization.

WO 2009/024977, by the present assignee, which is incorporated by reference as if fully set forth herein, teaches conjugates of a saccharide and a biomolecule, covalently linked therebetween via a non-hydrophobic linker, as well as medical uses utilizing such conjugates.

PCT International Patent Application No. PCT/IL2010/000956, by the present assignee, teaches methodologies which utilize α-galactosidase which exhibits a lysosomal activity at pH levels higher than lysosomal pH.

Additional background art include Bendele et al. [Toxicological Sciences 1998, 42:152-157], U.S. Pat. Nos. 5,256804, 5,580757 and 5,766,897, International Patent Application PCT/NL2007/050684 (published as WO 2008/075957), and Seely & Richey [J Chromatography A 2001, 908:235-2411].

SUMMARY OF THE INVENTION

According to an aspect of some embodiments of the present invention there is provided a multimeric protein structure comprising at least two α-galactosidase monomers being covalently linked to one another via a linking moiety, the multimeric protein structure featuring a characteristic selected from the group consisting of:

(a) an α-galactosidase activity upon subjecting the multimeric protein structure to human plasma conditions for one hour, which is at least 10% higher than an activity of native α-galactosidase upon subjecting the native α-galactosidase to human plasma conditions for one hour;

(b) an α-galactosidase activity which decreases upon subjecting the multimeric protein structure to human plasma conditions for one hour by a percentage which is at least 10% less than the percentage by which an activity of the native α-galactosidase decreases upon subjecting the native α-galactosidase to human plasma conditions for one hour;

(c) an α-galactosidase activity which remains substantially unchanged upon subjecting the multimeric protein structure to human plasma conditions for one hour;

(d) an α-galactosidase activity, upon subjecting the multimeric protein structure to lysosomal conditions for one week, which is at least 10% higher than an activity of native α-galactosidase upon subjecting the native α-galactosidase to lysosomal conditions for one week;

(e) an α-galactosidase activity which decreases upon subjecting the multimeric protein structure to lysosomal conditions for one day by a percentage which is at least 10% less than the percentage by which an activity of the native α-galactosidase decreases upon subjecting the native α-galactosidase to lysosomal conditions for one day;

(f) an α-galactosidase activity which remains substantially unchanged upon subjecting the multimeric protein structure to lysosomal conditions for one day;

(g) an α-galactosidase activity, immediately upon subjecting the multimeric protein structure to lysosomal conditions, which is at least 10% higher than an activity of native α-galactosidase immediately upon subjecting the native form of the protein to lysosomal conditions;

(h) an α-galactosidase activity, immediately upon subjecting the multimeric protein structure to an aqueous solution having a pH of 7 and a temperature of 37° C., which is at least 10% higher than an activity of native α-galactosidase immediately upon subjecting the native α-galactosidase to an aqueous solution having a pH of 7 and a temperature of 37° C.; and

(i) a circulating half-life in a physiological system which is higher by at least 20% than the circulating half-life of the native α-galactosidase.

According to an aspect of some embodiments of the present invention there is provided a multimeric protein structure comprising at least two α-galactosidase monomers being covalently linked to one another via a linking moiety, wherein the linking moiety is not present in native α-galactosidase.

According to an aspect of some embodiments of the present invention there is provided a pharmaceutical composition comprising a multimeric protein structure as described herein and a pharmaceutically acceptable carrier.

According to an aspect of some embodiments of the present invention there is provided a method of treating Fabry disease, the method comprising administering to a subject in need thereof a therapeutically effective amount of a multimeric protein structure as described herein, thereby treating the Fabry disease.

According to an aspect of some embodiments of the present invention there is provided a process of preparing a multimeric protein structure as described herein, the process comprising reacting α-galactosidase with a cross-linking agent which comprises the linking moiety described herein and at least two reactive groups.

According to some embodiments of the invention, the linking moiety described herein is not present in native α-galactosidase.

According to some embodiments of the invention, the multimeric protein structure features a characteristic selected from the group consisting of:

(a) an α-galactosidase activity, upon subjecting the multimeric protein structure to human plasma conditions for one hour, which is at least 10% higher than an activity of native α-galactosidase upon subjecting the native α-galactosidase to human plasma conditions for one hour;

(b) an α-galactosidase activity which decreases upon subjecting the multimeric protein structure to human plasma conditions for one hour by a percentage which is at least 10% less than the percentage by which an activity of the native α-galactosidase decreases upon subjecting the native α-galactosidase to human plasma conditions for one hour;

(c) an α-galactosidase activity which remains substantially unchanged upon subjecting the multimeric protein structure to human plasma conditions for one hour;

(d) an α-galactosidase activity, upon subjecting the multimeric protein structure to lysosomal conditions for one week, which is at least 10% higher than an activity of native α-galactosidase upon subjecting the native α-galactosidase to lysosomal conditions for one week;

(e) an α-galactosidase activity which decreases upon subjecting the multimeric protein structure to lysosomal conditions for one day by a percentage which is at least 10% less than the percentage by which an activity of the native α-galactosidase decreases upon subjecting the native α-galactosidase to lysosomal conditions for one day;

(f) an α-galactosidase activity which remains substantially unchanged upon subjecting the multimeric protein structure to lysosomal conditions for one day;

(g) an α-galactosidase activity, immediately upon subjecting the multimeric protein structure to lysosomal conditions, which is at least 10% higher than an activity of native α-galactosidase immediately upon subjecting the native α-galactosidase to lysosomal conditions;

(h) an α-galactosidase activity, immediately upon subjecting the multimeric protein structure to an aqueous solution having a pH of 7 and a temperature of 37° C., which is at least 10% higher than an activity of native α-galactosidase immediately upon subjecting the native α-galactosidase to an aqueous solution having a pH of 7 and a temperature of 37° C.; and

(i) a circulating half-life in a physiological system which is higher than a circulating half-life of the native α-galactosidase.

According to some embodiments of the invention, the α-galactosidase activity of the multimeric protein structure which remains substantially unchanged upon subjecting the multimeric protein structure to lysosomal conditions for one day, further remains substantially unchanged upon subjecting the multimeric protein structure to lysosomal conditions for one week.

According to some embodiments of the invention, the circulating half-life of the multimeric protein structure which is higher than a circulating half-life of the native α-galactosidase, is higher by at least 20% than the circulating half-life of the native α-galactosidase.

According to some embodiments of the invention, the circulating half-life of the multimeric protein structure which is higher than a circulating half-life of the native α-galactosidase, is higher by at least 50% than the circulating half-life of the native α-galactosidase.

According to some embodiments of the invention, the multimeric protein structure is characterized by an α-galactosidase activity in an organ upon administration of the multimeric protein structure to a vertebrate, the organ being selected from the group consisting of a spleen, a heart and a kidney.

According to some embodiments of the invention, the multimeric protein structure comprises two α-galactosidase monomers, the protein structure being a dimeric protein structure.

According to some embodiments of the invention, the α-galactosidase is a human α-galactosidase.

According to some embodiments of the invention, the α-galactosidase is a plant recombinant α-galactosidase.

According to some embodiments of the invention, the α-galactosidase has an amino acids sequence selected from the group consisting of SEQ ID NO:1, SEQ ID NO:2 and SEQ ID NO:3.

According to some embodiments of the invention, the α-galactosidase is an alkaline α-galactosidase.

According to some embodiments of the invention, the α-galactosidase is an acid α-galactosidase.

According to some embodiments of the invention, the linking moiety comprises a poly(alkylene glycol).

According to some embodiments of the invention, the poly(alkylene glycol) comprises at least two functional groups, each functional group forming a covalent bond with one of the α-galactosidase monomers.

According to some embodiments of the invention, the at least two functional groups are terminal groups of the poly(alkylene glycol).

According to some embodiments of the invention, the at least one linking moiety has a general formula:

—X₁—(CR₁R₂—CR₃R₄—Y)n-X₂—

wherein each of X₁ and X₂ is a functional group that forms a covalent bond with at least one α-galactosidase monomer;

Y is O, S or NR₅;

n is an integer from 1 to 200; and

each of R₁, R₂, R₃, R₄ and R₅ is independently selected from the group consisting of hydrogen, alkyl, cycloalkyl, alkenyl, alkynyl, alkoxy, hydroxy, oxo, thiol and thioalkoxy.

According to some embodiments of the invention, at least one of the functional groups forms an amide bond with an α-galactosidase monomer.

According to some embodiments of the invention, n is an integer from 5 to 150.

According to some embodiments of the invention, n is an integer from 40 to 70.

According to some embodiments of the invention, the pharmaceutical composition further comprises a galactose.

According to some embodiments of the invention, the multimeric protein structure is for use as a medicament.

According to some embodiments of the invention, the medicament is for treating Fabry disease.

According to some embodiments of the invention, the multimeric protein structure is for use in treating Fabry disease.

According to some embodiments of the invention, the process comprises reacting dimeric α-galactosidase with the cross-linking agent.

According to some embodiments of the invention, the reactive groups comprise a leaving group.

According to some embodiments of the invention, the reactive group reacts with an amine group to form an amide bond.

According to some embodiments of the invention, each of the reactive groups is capable of forming a covalent bond between the linking moiety and at least one α-galactosidase monomer.

According to some embodiments of the invention, a molar ratio of the cross-linking agent to monomers of α-galactosidase is in a range of from 5:1 to 500:1.

According to some embodiments of the invention, the molar ratio is in a range of from 75:1 to 300:1.

Unless otherwise defined, all technical and/or scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the invention pertains. Although methods and materials similar or equivalent to those described herein can be used in the practice or testing of embodiments of the invention, exemplary methods and/or materials are described below. In case of conflict, the patent specification, including definitions, will control. In addition, the materials, methods, and examples are illustrative only and are not intended to be necessarily limiting.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

Some embodiments of the invention are herein described, by way of example only, with reference to the accompanying drawings. With specific reference now to the drawings in detail, it is stressed that the particulars shown are by way of example and for purposes of illustrative discussion of embodiments of the invention. In this regard, the description taken with the drawings makes apparent to those skilled in the art how embodiments of the invention may be practiced.

In the drawings:

FIG. 1 is a graph showing the activity of Fabrazyme® α-GAL, Replagal® α-GAL and plant recombinant human α-GAL-I, as a function of incubation time under simulated lysosomal conditions (citrate phosphate buffer, pH 4.6, 37° C.);

FIG. 2 is a graph showing the activity of Fabrazyme® α-GAL, Replagal® α-GAL, plant recombinant human α-GAL-I, and plant recombinant α-GAL-I with galactose (100 mg/mL), as a function of incubation time under simulated physiological conditions (pH 7.4, 37° C.);

FIG. 3 is a graph showing the activity of Fabrazyme® α-GAL, Replagal® α-GAL and plant recombinant human α-GAL-I, as a function of incubation time in human plasma at 37° C.;

FIG. 4 is a graph showing the activity of Fabrazyme® α-GAL, Replagal® α-GAL, plant recombinant human α-GAL-I, and plant recombinant α-GAL-I with galactose (100 mg/mL), as a function of incubation time under simulated lysosomal conditions (citrate phosphate buffer, pH 4.6, 37° C.);

FIG. 5 is a scheme depicting the molecular structures of exemplary bis-N-hydroxysuccinimide-poly(ethylene glycol) (bis-NHS-PEG) cross-linking agents;

FIG. 6 is a scheme depicting a dimeric protein which has been reacted with bis-NHS-PEG cross-linking agents;

FIG. 7 presents a scan of an SDS-PAGE gel showing plant recombinant α-GAL-I which was reacted with bis-NHS-PEG₅ (lanes 1-3), bis-NHS-PEG₈ (lanes 7-9), and bis-NHS-PEG₄₅ (lanes 4-6), at a molar ratio of 50:1 (lanes 1, 4 and 7), 100:1 (lanes 2, 5 and 8) and 200:1 (lanes 3, 6 and 9) bis-NHS-PEG:α-GAL, as well as molecular weight markers (Mw) and non-reacted plant recombinant α-GAL-I standard (Std) (arrows show the band comprising an α-GAL dimer);

FIG. 8 presents a scan of an isoelectric focusing gel showing plant recombinant α-GAL-I which was reacted with bis-NHS-PEG₅ (lanes 1-3), bis-NHS-PEG_(S) (lanes 7-9), and bis-NHS-PEG₄₅ (lanes 4-6), at a molar ratio of 50:1 (lanes 1, 4 and 7), 100:1 (lanes 2, 5 and 8) and 200:1 (lanes 3, 6 and 9) bis-NHS-PEG:α-GAL, as well as pH markers (M) and non-reacted plant recombinant α-GAL-I standard (Std) (arrows show pH values for various bands);

FIG. 9 is a MALDI-TOF mass spectroscopy spectrum of plant recombinant α-GAL-I cross-linked by bis-NHS-PEG₄₅ (x-axis indicates m/z values, and m/z values of peaks are shown);

FIG. 10 is a MALDI-TOF mass spectroscopy spectrum of plant recombinant α-GAL-I cross-linked by bis-NHS-PEG₈ (x-axis indicates m/z values, and m/z values of peaks are shown);

FIG. 11 presents a photograph showing the α-GAL substrate N-dodecanoyl-nitrobenzoxadiazole-ceramide trihexoside (Gb₃-NBD) and the α-GAL reaction product lactosyl ceramide-nitrobenzoxadiazole (lactosyl ceramide-NBD), as visualized by irradiation under UV light (365 nm) following high performance thin layer chromatography, following incubation of the substrate Gb₃-NBD with plant recombinant human α-GAL-I cross-linked with bis-NHS-PEG₄₅ (left lane), Replagal® α-GAL (middle lane) and without α-GAL (right lane);

FIGS. 12A, 12B and 12C, are graphs showing the activity of Fabrazyme® α-GAL, Replagal® α-GAL, plant recombinant human α-GAL-I, and plant recombinant human α-GAL-I cross-linked with bis-NHS-PEG₅ (FIG. 12A), bis-NHS-PEG₈ (FIG. 12B) and bis-NHS-PEG₄₅ (FIG. 12C) at a molar ratio of 50:1 (“1” in FIG. 12A, “7” in FIG. 12B and “4” in FIG. 12C), 100:1 (“2” in FIG. 12A, “8” in FIG. 12B and “5” in FIG. 12C) and 200:1 (“3” in FIG. 12A, “9” in FIG. 12B and “6” in FIG. 12C) bis-NHS-PEG:α-GAL as a function of incubation time under simulated lysosomal conditions (citrate phosphate buffer, pH 4.6, 37° C.);

FIG. 13 is a graph showing the pharmacokinetic profile of Replagal® α-GAL, plant recombinant human α-GAL-I, and plant recombinant human α-GAL-I cross-linked with bis-NHS-PEG₄₅ in the plasma of Fabry mice; the residual activity of each α-GAL is presented as a percentage of the maximal residual activity of each α-GAL, as a function of time following injection of the α-GALs;

FIGS. 14A and 14B present a graph (FIG. 14A) showing the activity of Replagal® α-GAL, plant recombinant human α-GAL-I (prh-alpha-GAL-I), and plant recombinant human α-GAL-I cross-linked with bis-NHS-PEG_(S) (prh-alpha-GAL-I-CL8) or bis-NHS-PEG₄₅ (prh-alpha-GAL-I-CL45) in the spleens of Fabry mice 2 hours following injection of α-GAL, and a photograph of a Western blot (FIG. 14B) showing Replagal® α-GAL (lanes 10-12 and 15), plant recombinant human α-GAL-I (lanes 7-9 and 13), and plant recombinant human α-GAL-I cross-linked with bis-NHS-PEG_(S) (lanes 4-6) or bis-NHS-PEG₄₅ (lanes 1-3 and 14) in the spleens of Fabry mice following injection of α-GAL (lanes 1-12) or as a standard consisting of 50 ng α-GAL (lanes 13-15);

FIGS. 15A and 15B present a graph (FIG. 15A) showing the activity of Replagal® α-GAL, plant recombinant human α-GAL-I (prh-alpha-GAL-I), and plant recombinant human α-GAL-I cross-linked with bis-NHS-PEG₈ (prh-alpha-GAL-I-CL8) or bis-NHS-PEG₄₅ (prh-alpha-GAL-I-CL45) in the livers of Fabry mice 2 hours following injection of α-GAL, and a photograph of a Western blot (FIG. 15B) showing Replagal® α-GAL (lanes 10-12 and 15), plant recombinant human α-GAL-I (lanes 7-9 and 13), and plant recombinant human α-GAL-I cross-linked with bis-NHS-PEG₈ (lanes 4-6) or bis-NHS-PEG₄₅ (lanes 1-3 and 14) in the livers of Fabry mice following injection of α-GAL (lanes 1-12) or as a standard consisting of 50 ng α-GAL (lanes 13-15);

FIG. 16 is a graph showing the activity of Replagal® α-GAL, plant recombinant human α-GAL-I (prh-alpha-GAL-I), and plant recombinant human α-GAL-I cross-linked with bis-NHS-PEG₈ (prh-alpha-GAL-I-) or bis-NHS-PEG₄₅ (prh-alpha-GAL-I-CL45) in the hearts of Fabry mice 2 hours following injection of α-GAL;

FIG. 17 is a graph showing the activity of Replagal® α-GAL, plant recombinant human α-GAL-I (prh-alpha-GAL-I), and plant recombinant human α-GAL-I cross-linked with bis-NHS-PEG₈ (prh-alpha-GAL-I-CL8) or bis-NHS-PEG₄₅ (prh-alpha-GAL-I-CL45) in the kidneys of Fabry mice 2 hours following injection of α-GAL;

FIG. 18 is a graph showing the activity of Replagal® α-GAL and plant recombinant human α-GAL-I (prh-alpha-GAL-I), and plant recombinant human α-GAL-I cross-linked with bis-NHS-PEG₄₅ (prh-alpha-GAL-I-CL45) in the spleens of Fabry mice 2 hours, 24 hours, 3 days and 7 days following injection of α-GAL (endogenous wild type α-GAL (WT) is shown as a standard);

FIG. 19 is a graph showing the activity of Replagal® α-GAL and plant recombinant human α-GAL-I (prh-alpha-GAL-I), and plant recombinant human α-GAL I cross-linked with bis-NHS-PEG₄₅ (prh-alpha-GAL-I-CL45) in the livers of Fabry mice 2 hours, 24 hours, 3 days and 7 days following injection of α-GAL (endogenous wild type α-GAL (WT) is shown as a standard);

FIG. 20 is a graph showing the activity of Replagal® α-GAL and plant recombinant human α-GAL-I (prh-alpha-GAL-I), and plant recombinant human α-GAL-I cross-linked with bis-NHS-PEG₄₅ (prh-alpha-GAL-I-CL45) in the hearts of Fabry mice 2 hours, 24 hours, 3 days and 7 days following injection of α-GAL (endogenous wild type α-GAL (WT) is shown as a standard);

FIG. 21 is a graph showing the activity of Replagal® α-GAL and plant recombinant human α-GAL-I (prh-alpha-GAL-I), and plant recombinant human α-GAL-I cross-linked with bis-NHS-PEG₄₅ (prh-alpha-GAL-I-CL45) in the kidneys of Fabry mice 2 hours, 24 hours, 3 days and 7 days following injection of α-GAL (endogenous wild type α-GAL (WT) is shown as a standard);

FIG. 22 presents a photograph of an image of an SDS-PAGE gel showing Replagal® mammalian recombinant human α-GAL (left lane), and Replagal® mammalian recombinant human α-GAL which was reacted with bis-NHS-PEG₄₅ (middle lane), as well as molecular weight markers (right lane; molecular weights of markers are indicated in KDa units);

FIG. 23 presents a photograph of an isoelectric focusing gel showing Replagal® mammalian recombinant human α-GAL (left lane), and Replagal® mammalian recombinant human α-GAL which was reacted with bis-NHS-PEG₄₅ (middle lane), as well as pH markers (right lane);

FIGS. 24A and 24B are MALDI-TOF mass spectroscopy spectra of Replagal® mammalian recombinant human α-GAL (FIG. 24A), and Replagal® mammalian recombinant human α-GAL cross-linked by bis-NHS-PEG₄₅ (x-axis indicates m/z values, and m/z values (in Da units) of peaks are shown);

FIG. 25 is a Michaelis-Menten plot showing the velocity (V) of hydrolysis of p-nitrophenyl-α-D-galactopyranoside (pNP-G) by Replagal® mammalian recombinant human α-GAL (Replagal) and Replagal® mammalian recombinant human α-GAL cross-linked by bis-NHS-PEG₄₅ (Replagal CL45), as a function of pNP-G concentration;

FIGS. 26A and 26B are graphs showing the activity of Replagal® mammalian recombinant human α-GAL (Replagal) and Replagal® mammalian recombinant human α-GAL cross-linked by bis-NHS-PEG₄₅ (Replagal-CL45) as a function of incubation time under simulated lysosomal conditions (citrate phosphate buffer, pH 4.6, 37° C.) (FIG. 26A) or in human plasma at 37° C. (FIG. 26B);

FIGS. 27A-27D are graphs showing the activity of Replagal® α-GAL (R) and Replagal® α-GAL cross-linked with bis-NHS-PEG₄₅ (R-CL45) in the spleens (FIG. 27A), livers (FIG. 27B), hearts (FIG. 27C) and kidneys (FIG. 27D) of Fabry mice 2 hours following injection of α-GAL;

FIGS. 28A-28D are graphs showing Gb₃ levels in the hearts (FIG. 28A), kidneys (FIG. 28B), livers (FIG. 28C) and spleens (FIG. 28D) of Fabry mice, as a function of time following injection of Replagal® α-GAL (R) or Replagal® α-GAL cross-linked with bis-NHS-PEG₄₅ (R-CL45);

FIGS. 29A and 29B present scans of SDS-PAGE gels showing plant recombinant human α-GAL-II (FIGS. 29A and 29B, lane 2), and plant recombinant human α-GAL-II which was reacted with bis-NHS-PEG₂₁ (FIG. 29A, lane 3), bis-NHS-PEG₄₅ (FIG. 29A, lane 4) or bis-NHS-PEG₆₈ (FIG. 29B, lane 3), as well as molecular weight markers (FIGS. 29A and 29B, lane 1; molecular weights of markers are indicated in KDa units);

FIGS. 30A-30C are MALDI-TOF mass spectroscopy spectra of plant recombinant human α-GAL-II (FIG. 30A), and plant recombinant human α-GAL-II cross-linked by bis-NHS-PEG₂₁ (FIG. 30B) or bis-NHS-PEG₄₅ (FIG. 30C) (x-axis indicates m/z values, and m/z values (in Da units) of peaks are shown);

FIGS. 31A-31D are graphs showing the activity of Replagal® mammalian recombinant human α-GAL (Replagal), plant recombinant human α-GAL-II (prh-alpha-GAL-II) and plant recombinant human α-GAL-II cross-linked by bis-NHS-PEG₂₁ (prh-alpha-GAL-II-CL21; FIGS. 31A and 31C), bis-NHS-PEG₄₅ (prh-alpha-GAL-II-CL45; FIGS. 31A-31D) or bis-NHS-PEG₆₈ (prh-alpha-GAL-II-CL68; FIGS. 31B and 31D) as a function of incubation time under simulated lysosomal conditions (citrate phosphate buffer, pH 4.6, 37° C.) (FIGS. 31A and 31B) or in human plasma at 37° C. (FIGS. 31C and 31D) (data shown in FIGS. 31C and 31D are from different experiments);

FIGS. 32A and 32B are graphs showing the pharmacokinetic profiles of Replagal® α-GAL (Replagal), plant recombinant human α-GAL-II (prh-alpha-GAL-II), and plant recombinant human α-GAL-II cross-linked with bis-NHS-PEG₄₅ (prh-alpha-GAL-II-CL45) in the plasma of Fabry mice; concentration of each α-GAL is presented as a function of time following injection of α-GAL (FIGS. 32A and 32B present the same data at different time frames);

FIGS. 33A-33L are graphs showing the activity of Replagal® α-GAL (Replagal), plant recombinant human α-GAL-II (prh-alpha-GAL-II) and plant recombinant human α-GAL-II cross-linked with bis-NHS-PEG₄₅ (prh-alpha-GAL-II-CL45; FIGS. 33A-33L) or bis-NHS-PEG₂₁ (prh-alpha-GAL-II-CL21; FIGS. 33E-33L) in the hearts (FIGS. 33A, 33E and 33I), kidneys (FIGS. 33B, 33F and 33J), livers (FIGS. 33C, 33G and 33K) and spleens (FIGS. 33D, 33H and 33L) of Fabry mice 2 hours (FIGS. 33A-33H), 7 days (FIGS. 33A-33D and 33I-33L), 14 days (FIGS. 33A-33D) and 28 days (FIGS. 33A-33D) following injection of α-GAL;

FIGS. 34A-34C are graphs showing the kinetic parameters V_(max) (FIG. 34A), K_(M) (FIG. 34B) and k_(eat) (FIG. 34C) for plant recombinant human α-GAL-II (prh-alpha-GAL-II) and plant recombinant human α-GAL-II cross-linked with bis-NHS-PEG₄₅ (prh-alpha-GAL-II-CL45), as a function of pH;

FIG. 35 presents a scan of an SDS-PAGE gel showing plant recombinant human α-GAL-I (prh-α-Gal-I), and plant recombinant human α-GAL-I which was reacted with methoxy-capped NHS-PEG having a molecular weight of 2 KDa (prh-α-Gal-I-PEG 2000), 5 KDa (prh-α-Gal-I-PEG 5000) or 10 KDa (prh-α-Gal-I-PEG 10000), as well as molecular weight markers (left lane; molecular weights of markers are indicated in KDa units);

FIGS. 36A and 36B are graphs showing the activity of Fabrazyme® mammalian recombinant human α-GAL (Fabrazyme), Replagal® mammalian recombinant human α-GAL (Replagal), plant recombinant human α-GAL-I and plant recombinant human α-GAL-I which was reacted with methoxy-capped NHS-PEG having a molecular weight of 2 KDa (α-Gal-I-PEG 2000), 5 KDa (α-Gal-I-PEG 5000) or 10 KDa (α-Gal-I-PEG 10000), as a function of incubation time under simulated lysosomal conditions (citrate phosphate buffer, pH 4.6, 37° C.) (FIG. 36A) or in human plasma at 37° C. (FIG. 36B);

FIG. 37 presents a scan of an SDS-PAGE gel showing plant recombinant α-GAL-I which was reacted with bis-NHS-PEG₂ (lanes 1-3), bis-NHS-PEG₄ (lanes 4-6), bis-NHS-PEG₆₈ (lanes 7-9), bis-NHS-PEG₁₅₀ (lanes 10-12) and bis-NHS-PEG₄₅ (CL45), at a molar ratio of 50:1 (lanes 1, 4, 7 and 10), 100:1 (lanes 2, 5, 8 and 11) and 200:1 (lanes 3, 6, 9 and 12) bis-NHS-PEG:α-GAL, as well as molecular weight markers (MW);

FIG. 38 presents a scan of an SDS-PAGE gel showing plant recombinant α-GAL-I which was reacted with bis-COOH-PEG₁₂ (lanes 1-3), bis-COOH-PEG₂₈ (lanes 4-6), bis-COOH-PEG₄₅ (lanes 7-9), and bis-NHS-PEG₄₅ (CL45), at a molar ratio of 50:1 (lanes 1, 4 and 7), 100:1 (lanes 2, 5 and 8) and 200:1 (lanes 3, 6 and 9) bis-NHS-PEG:α-GAL, as well as molecular weight markers (MW), and non-crosslinked plant recombinant α-GAL-I as a control (con);

FIG. 39 is a graph showing the activity of Replagal® α-GAL, plant recombinant human α-GAL-I (prh-α-GAL-I), and plant recombinant human α-GAL-I cross-linked with bis-NHS-PEG₄₅ (prh-α-GAL-I-CL45), bis-NHS-PEG₄ (prh-α-GAL-I-CL4), bis-NHS-PEG₂ (prh-α-GAL-I-CL2), bis-COOH-PEG₄₅ (prh-α-GAL-I-CLA45) bis-COOH-PEG₂₈ (prh-α-GAL-I-CLA28) or bis-COOH-PEG₁₂ (prh-α-GAL-I-CLA12) as a function of incubation time under simulated lysosomal conditions (citrate phosphate buffer, pH 4.6, 37° C.);

FIGS. 40A and 40B are graphs showing the activity of plant recombinant human α-GAL-II cross-linked by bis-NHS-PEG₄₅ as a function of incubation time under simulated lysosomal conditions (citrate phosphate buffer, pH 4.6, 37° C.) (FIG. 40A) or in human plasma at 37° C. (FIG. 40B) (FIG. 40B shows the activity of Replagal® mammalian recombinant α-GAL and non-cross-linked plant recombinant human α-GAL-II for comparison);

FIG. 41 presents a scan of an SDS-PAGE gel showing plant recombinant α-GAL-II from 3 different batches (lanes 1-3) and plant recombinant α-GAL-II which was reacted with bis-NHS-PEG₄₅ from 5 different batches (lanes 4-8), as well as molecular weight markers (MW);

FIG. 42 presents a scan of an isoelectric focusing gel showing plant recombinant α-GAL-II from 3 different batches (lanes 1-3) and plant recombinant α-GAL-II which was reacted with bis-NHS-PEG₄₅ from 5 different batches (lanes 4-8), as well as pH markers (M);

FIGS. 43A-43F are MALDI-TOF mass spectroscopy spectra of plant recombinant human α-GAL-II (FIG. 43A), and plant human α-GAL-II cross-linked by bis-NHS-PEG₄₅ from 5 different batches (FIGS. 43B-43F, respectively) (x-axis indicates m/z values, and m/z values (in Da units) of peaks are shown); and

FIG. 44 is a graph showing the catalytic velocity (V) of α-GAL activity exhibited by plant human α-GAL-II cross-linked by bis-NHS-PEG₄₅ from 5 different batches, as a function of substrate (p-nitrophenyl-α-D-galactopyranoside) concentration.

DESCRIPTION OF SPECIFIC EMBODIMENTS OF THE INVENTION

The present invention, in some embodiments thereof, relates to novel multimeric protein structures and, more particularly, but not exclusively, to multimeric protein structures of α-galactosidase and to uses thereof in treating Fabry disease.

Before explaining at least one embodiment of the invention in detail, it is to be understood that the invention is not necessarily limited in its application to the details set forth in the following description or exemplified by the Examples. The invention is capable of other embodiments or of being practiced or carried out in various ways.

Deficiencies of a lysosomal protein (e.g., defects in a lysosomal protein or absence of a lysosomal protein) can cause considerable harm to the health of a subject (a lysosomal storage disease). Enzyme replacement therapy (ERT), in which the deficient protein is administered to a patient, has been used in attempts to treat lysosomal storage diseases. However, administration of the deficient protein does not necessarily result in a considerable and/or persistent increase in the activity of the protein in vivo.

Fabry disease is an example of an X-linked recessive (inherited) lysosomal storage disease which can cause a wide range of systemic symptoms. A deficiency of the lysosomal enzyme α-galactosidase A due to mutation causes a glycolipid known as globotriaosylceramide (also known as Gb₃ or ceramide trihexoside) to accumulate within the blood vessels, other tissues, and organs. This accumulation leads to an impairment of their proper function. Two enzyme replacement therapies (ERTs) are available to functionally compensate for α-galactosidase deficiency. Agalsidase alpha (Replagal®, Shire) and agalsidase beta (Fabrazyme®, Genzyme) are both recombinant forms of the human α-galactosidase A enzyme. These enzymes are difficult to manufacture and as such are expensive. Recently, contamination at Genzyme's Allston, MA, plant caused a worldwide shortage of agalsidase beta, and supplies were rationed to patients at one-third the recommended dose.

As shown herein, α-galactosidases exert their maximal activity at low pH levels characteristic of lysosomes, while their activity at higher pH levels is compromised. Thus, for example, α-galactosidase used in ERT would have little ability to hydrolyze terminal galactosylated glycolipids in the serum of Fabry patients.

Moreover, as further shown herein, even under lysosomal conditions, the activity of α-galactosidases is gradually compromised, although at a slower rate than at higher pH levels.

Motivated by a need to solve the compromised activity of α-galactosidases, the present inventors have searched for stabilized forms of α-galactosidase (α-GAL). More specifically, the present inventors have envisioned that a stabilized form of α-galactosidase would exhibit longer lasting activity in general, including longer lasting activity in serum. The present inventors have thus designed and successfully prepared and practiced stabilized forms of native α-galactosidase and have indeed shown that such stabilized forms exhibit an improved performance, in terms of enhanced activity and/or a longer lasting activity under both lysosomal conditions and in a serum environment, which allows for an enhanced activity of the protein in vivo.

The present inventors have demonstrated a formation of stabilized forms of α-galactosidase which exhibit an improved performance by means of cross-linking native α-galactosidase, via formation of new covalent linkage between α-galactosidase monomers.

Referring now to the drawings, FIGS. 1 and 4 show the decline of enzyme activity under lysosomal conditions for plant recombinant human α-GAL I (prh-α-GAL I) and Fabrazyme® and Replagal® α-GAL. FIGS. 2 and 3 show the decline of enzyme activity under simulated physiological conditions or in human plasma, for the same α-GAL varieties. FIGS. 2 and 4 show that galactose decreases the rate of the decline in α-GAL activity.

FIG. 5 shows exemplary PEG (polyethylene glycol) cross-linking agents, according to optional embodiments of the invention. FIG. 6 depicts a cross-linked α-GAL dimer according to optional embodiments of the invention.

FIGS. 7-10 and 37 show that prh-α-GAL-I reacted with exemplary cross-linking agents comprising N-hydroxysuccinimide moieties. FIG. 38 shows that prh-α-GAL-I reacted with exemplary cross-linking agents comprising carboxyl groups, following in situ activation with N-hydroxysuccinimide. FIGS. 7, 37 and 38 show that the reaction with the cross-linking agent resulted in α-GAL appearing primarily in a dimeric form rather than a monomeric form under denaturing conditions, indicating that the quaternary structure of the α-GAL was maintained by covalent cross-linking. FIG. 11 shows that the cross-linked α-GAL retained its enzymatic activity.

FIGS. 12A-12C and 39 show that the cross-linked prh α-GAL-I exhibits a longer lasting activity than non-cross-linked α-GAL under simulated lysosomal conditions. The increase in stability is stronger for PEG₂₈ and PEG₄₅ linkers than for shorter PEG linkers. FIG. 13 shows that the cross-linked prh-α-GAL-I exhibits a longer lasting activity than non-cross-linked α-GAL in plasma in vivo. FIGS. 14A-21 show that cross-linked prh-α-GAL-I exhibits an enhanced activity in vivo in the spleen, liver, heart and kidneys. The enhancement of α-GAL activity is stronger for PEG₄₅ linkers than for shorter PEG linkers. FIGS. 15A, 15B and 19 show that although cross-linked prh-α-GAL-I exhibits an enhanced activity in vivo, the enhanced activity is not as concentrated in the liver as is Replagal® α-GAL activity.

The above results indicate that cross-linking plant recombinant human α-GAL-I results in a dimer with improved stability, which allows for a more effective increase of α-GAL activity when administered in vivo.

Similarly, FIGS. 22-28D show that cross-linking mammalian recombinant human α-GAL results in a covalently-linked dimer (FIGS. 22-24B), which exhibits normal enzymatic activity (FIG. 25), as well as longer lasting activity under both lysosomal conditions and in plama (FIGS. 26A-26B), and enhanced activity in vivo in the spleen, liver, heart and kidneys (FIGS. 27A-28D).

Similarly, FIGS. 29A-33L show that cross-linking plant recombinant human α-GAL II results in a covalently-linked dimer (FIGS. 29-30), which exhibits longer lasting activity under both lysosomal conditions and in plama (FIGS. 31A-31B), and enhanced activity in vivo in plasma and in the spleen, liver, heart and kidneys (FIGS. 32A-33L). As shown in FIGS. 33A-33L, cross-linking with a PEG₄₅ linker was particularly effective at enhancing in vivo activity.

These results indicate that the advantageous effects of cross-linking are applicable to a variety of α-GAL proteins.

FIGS. 34A-34C show that cross-linking α-GAL enhances parameters of α-GAL enzymatic catalysis, broadens the pH range for α-GAL activity, and allows for α-GAL activity at a pH of about 7 or more.

FIGS. 35-36B show that PEGylation without cross-linking has no significant effect on α-GAL activity, indicating that the advantageous effects of cross-linking are specifically due to cross-linking, rather than to an effect of PEGylation.

FIGS. 40-44 show that cross-linking of α-GAL according to embodiments of the invention allows for good reproducibility of the stability (FIGS. 40A-40B), degree of covalent cross-linking (FIGS. 41-43F) and enzymatic properties (FIG. 44) of the cross-linked α-GAL.

The results presented herein show that covalently cross-linked, multimeric protein structures of α-galactosidase are characterized by a higher stability and enhanced activity under physiologically relevant conditions, as compared to the native forms of α-galactosidase.

Thus, the covalently-linked multimeric protein structure may exhibit an activity which is higher than an activity of a native form of α-galactosidase, as a result of the activity of the native form decaying more rapidly over time than the activity of the cross-linked multimeric protein structure, which is stabilized by the covalent cross-linking.

The covalently cross-linked multimeric protein structure may exhibit an activity which is higher than an activity of a native form of α-galactosidase, also due to a higher initial activity (e.g., due to different parameters of activity), i.e., independently of any decay of activity over time.

Hence, according to an aspect of some embodiments of the present invention there is provided a multimeric protein structure comprising at least two α-galactosidase monomers being covalently linked to one another via a linking moiety. According to some embodiments, the multimeric protein structure features a stability higher than that of native α-galactosidase and/or an initial activity higher than that of native α-galactosidase, as described in detail below.

Herein, the term “monomer” with respect to α-galactosidase refers to an individual polypeptide of α-galactosidase. The polypeptide may include non-peptidic substituents (e.g., one or more saccharide moieties).

Herein, the term “native” with respect to α-galactosidase encompasses proteins comprising an amino acid sequence substantially identical (i.e., at least 95% homology, optionally at least 99% homology, and optionally 100%) to an amino acid sequence of a naturally occurring α-galactosidase protein. A native α-galactosidase may be a protein isolated from a natural source, or a recombinantly produced protein (e.g., derived from mammalian cells, plant cells, yeast cells, bacterial cells, insect cells).

The term “native”, when used in reference to a quaternary structure of α-galactosidase (e.g., an α-galactosidase dimer), further comprises a quaternary structure substantially identical to that of a naturally occurring protein.

Herein, the phrase “naturally occurring protein” refers to a protein in a form which occurs in nature (e.g., in an organism), with respect to the protein's amino acid sequence, as well as the protein's quaternary structure if the protein is in a multimeric form.

Post-translational modifications (e.g., glycosylation) of naturally occurring α-galactosidase proteins (e.g., in an organism which expresses the naturally occurring α-galactosidase protein) may be present, absent or modified in the native form of α-galactosidase referred to herein. A native form of α-galactosidase (e.g., a recombinantly produced α-galactosidase) may optionally comprise different post-translational modifications than those of the naturally occurring α-galactosidase, provided that the native form of the α-galactosidase retains a substantially similar amino acid sequence and structure as the naturally occurring α-galactosidase, as described hereinabove.

Herein, the native form of a protein may refer to a monomeric structure (e.g., an α-galactosidase monomer) and/or a multimeric structure (e.g., an α-galactosidase dimer). For example, a dimeric protein can be described as a native form of α-galactosidase, and a monomeric polypeptide in a dimeric protein can be described as a native form of the α-galactosidase monomer.

Optionally, the multimeric protein structure described herein is a dimeric structure, as is the native form of α-galactosidase.

Alternatively, the multimeric protein structure comprises more than two α-galactosidase monomers. For example, the multimeric protein structure may be a tetramer, a hexamer, or an octamer comprised of α-galactosidase monomers.

The multimeric protein structures described herein comprise covalent bonds which link the α-galactosidase monomers therein, and which are absent from the native form of the α-galactosidase.

Optionally, the linking moiety which links the α-galactosidase monomers is a moiety which is not present in a native form of α-galactosidase (e.g., a synthetic linking moiety).

Thus, for example, the linking moiety is optionally a moiety which is covalently attached to a side chain, an N-terminus or a C-terminus, or a moiety related to post-translational modifications (e.g., a saccharide moiety) of an α-galactosidase monomer, as well as to a side chain, an N-terminus or a C-terminus, or a moiety related to post-translational modifications (e.g., a saccharide moiety) of another α-galactosidase monomer. Exemplary such linking moieties are described in detail hereinunder.

Alternatively, the linking moiety forms a part of the α-galactosidase monomers being linked (e.g., a part of a side chain, N-terminus or C-terminus, or a moiety related to post-translational modifications (e.g., a saccharide moiety) of an α-galactosidase monomer, as well as of a side chain, an N-terminus or a C-terminus, or a moiety related to post-translational modifications (e.g., a saccharide moiety) of another α-galactosidase monomer).

Thus, for example, the linking moiety can be a covalent bond (e.g., an amide bond) between a functional group of a side chain, N-terminus, C-terminus or moiety related to post-translational modifications of a monomer (e.g., an amine), and a complementary functional group of a side chain, N-terminus, C-terminus or moiety related to post-translational modifications of another monomer (e.g., carboxyl), wherein such a covalent bond is absent from the native form of the α-galactosidase. Other covalent bonds, such as, for example, an ester bond (between a hydroxy group and a carboxyl); a thioester bond; an ether bond (between two hydroxy groups); a thioether bond; an anhydride bond (between two carboxyls); a thioamide bond; a carbamate or thiocarbamate bond, are also contemplated.

Optionally, the linking moiety is devoid of a disulfide bond. However, a linking moiety which includes a disulfide bond at a position which does not form a link between monomers (e.g., cleavage of the disulfide bond does not cleave the link between the monomers) is within the scope of this embodiment of the invention. A potential advantage of linking moiety devoid of a disulfide bond is that it is not susceptible to cleavage by mildly reducing conditions, as are disulfide bonds.

Optionally, the linking moiety is a non-peptidic moiety (e.g., the linking moiety does not consist of an amide bond, an amino acid, a dipeptide, a tripeptide, an oligopeptide or a polypeptide).

Alternatively, the linking moiety may be, or may comprise, a peptidic moiety (e.g., an amino acid, a dipeptide, a tripeptide, an oligopeptide or a polypeptide).

Optionally, the linking moiety is not merely a linear extension of any of the α-galactosidase monomers attached thereto (i.e., the N-terminus and C-terminus of the peptidic moiety is not attached directly to the C-terminus or N-terminus of any of the α-galactosidase monomers).

Alternatively, the linking moiety is formed by direct covalent attachment of an N-terminus of an α-galactosidase monomer with a C-terminus of another α-galactosidase monomer, so as to produce a fused polypeptide. Such a polypeptide will not be a native form of α-galactosidase, although it may comprise two α-galactosidase monomers essentially in their native form.

However, the covalent linking of α-galactosidase monomers described herein is preferably in a form other than direct linkage of an N-terminus to a C-terminus.

The linking moiety is also referred to herein as a cross-linking moiety. The linking of α-galactosidase monomers by a linking moiety is referred to herein as “cross-linking”.

The cross-linking moiety can be a covalent bond, a chemical atom or group (e.g., a C(═O)—O- group, —O—, —S—, NR—, —N═N—, —NH—C(═O)—NH—, and the like) or a bridging moiety (composed of a chain of chemical groups).

A bridging moiety can be, for example, a polymeric or oligomeric group.

The bridging moiety is a multifunctional moiety (e.g., biradical, triradical, etc.) that is attached to side chains, moieties related to post-translational modifications (e.g., saccharide moieties) and/or termini (i.e., N-termini, C-termini) of two or more of the monomers.

As exemplified herein in the Examples section, relatively short linking moieties (e.g., PEG₂, PEG₄, PEG₅) may be less effective than longer linking moieties (e.g., PEG₂₈, PEG₄₅) at cross-linking between different α-galactosidase monomers.

Hence, according to some embodiments, the linking moiety is not a covalent bond, a chemical atom or group, but is rather a bridging moiety.

Hence, according to some embodiments, the linking moiety is at least 10 atoms long, optionally at least 20 atoms long, optionally at least 30 atoms long, optionally at least 50 atoms long, optionally at least 100 atoms long, and optionally at least 200 atoms long.

Herein, the length of a linking moiety (when expressed as a number of atoms) refers to length of the backbone of the linking moiety, i.e., the number atoms forming a linear chain between residues of each of two monomers linked via the linking moiety.

Optionally, the linking moiety is below a certain size, so as to avoid an unnecessarily excessive part of the linking moiety in the formed cross-linked protein, which may interfere with the function of the protein.

Hence, according to some embodiments, each linking moiety is characterized by a molecular weight of less than 20 KDa, optionally less than 10 KDa, optionally less than 5 KDa, and optionally less than 3 KDa.

In order to facilitate cross-linking, the linking moiety is optionally substantially flexible, wherein the bonds in the backbone of the linking moiety are mostly rotationally free, for example, single bonds which are not coupled to a double bond (e.g., unlike an amide bond) and wherein rotation is not sterically hindered. Optionally, at least 70%, optionally at least 80%, and optionally at least 90% (e.g., 100%) of the bonds in the backbone of the linking moiety are rotationally free.

In some embodiments, the linking moiety comprises a poly(alkylene glycol) chain.

The phrase “poly(alkylene glycol)”, as used herein, encompasses a family of polyether polymers which share the following general formula: —O—[(CH₂)_(m)—O—]_(n)—, wherein m represents the number of methylene groups present in each alkylene glycol unit, and n represents the number of repeating units, and therefore represents the size or length of the polymer. For example, when m=2, the polymer is referred to as a polyethylene glycol, and when m=3, the polymer is referred to as a polypropylene glycol.

In some embodiments, m is an integer greater than 1 (e.g., m=2, 3, 4, etc.).

Optionally, m varies among the units of the poly(alkylene glycol) chain. For example, a poly(alkylene glycol) chain may comprise both ethylene glycol (m=2) and propylene glycol (m=3) units linked together.

The poly(alkylene glycol) optionally comprises at least two functional groups (e.g., as described herein), each functional group forming a covalent bond with one of the α-galactosidase monomers. The functional groups are optionally terminal groups of the poly(alkylene glycol), such that the entire length of the poly(alkylene glycol) lies between the two functional groups.

The phrase “poly(alkylene glycol)” also encompasses analogs thereof, in which the oxygen atom is replaced by another heteroatom such as, for example, S, —NH— and the like. This term further encompasses derivatives of the above, in which one or more of the methylene groups composing the polymer are substituted. Exemplary substituents on the methylene groups include, but are not limited to, alkyl, cycloalkyl, alkenyl, alkynyl, alkoxy, hydroxy, oxo, thiol and thioalkoxy, and the like.

The phrase “alkylene glycol unit”, as used herein, encompasses a —(CH₂)_(m)—O—group or an analog thereof, as described hereinabove, which forms the backbone chain of the poly(alkylene glycol), wherein the (CH₂)_(m) (or analog thereof) is bound to a heteroatom belonging to another alkylene glycol unit or to an α-galactosidase monomer moiety (in cases of a terminal unit), and the O (or heteroatom analog thereof) is bound to the (CH₂)_(m) (or analog thereof) of another alkylene glycol unit, or to a functional group which forms a bond with an α-galactosidase monomer.

An alkylene glycol unit may be branched, such that it is linked to 3 or more neighboring alkylene glycol units, wherein each of the 3 or more neighboring alkylene glycol units are part of a poly(alkylene glycol) chain. Such a branched alkylene glycol unit is linked via the heteroatom thereof to one neighboring alkylene glycol unit, and heteroatoms of the remaining neighboring alkylene glycol units are each linked to a carbon atom of the branched alkylene glycol unit. In addition, a heteroatom (e.g., nitrogen) may bind more than one carbon atom of an alkylene glycol unit of which it is part, thereby forming a branched alkylene glycol unit (e.g., [(—CH₂)_(m)]₂N— and the like).

In exemplary embodiments, at least 50% of alkylene glycol units are identical, e.g., they comprise the same heteroatoms and the same m values as one another. Optionally, at least 70%, optionally at least 90%, and optionally 100% of the alkylene glycol units are identical. In exemplary embodiments, the heteroatoms bound to the identical alkylene glycol units are oxygen atoms. In further exemplary embodiments, m is 2 for the identical units.

In one embodiment, the linker is a single, straight chain linker, preferably being polyethylene glycol (PEG).

As used herein, the term “poly(ethylene glycol)” describes a poly(alkylene glycol), as defined hereinabove, wherein at least 50%, at least 70%, at least 90%, and preferably 100%, of the alkylene glycol units are —CH₂CH₂—O—. Similarly, the phrase “ethylene glycol units” is defined herein as units of —CH₂CH₂O—.

According to optional embodiments, the linking moiety comprises a poly(ethylene glycol) or analog thereof, having a general formula:

—X₁—(CR₁R₂—CR₃R₄—Y)_(n)—X₂—

wherein each of X₁ and X₂ is a functional group (e.g., as described herein) that forms a covalent bond with at least one α-galactosidase monomer;

Y is O, S or NR_(S) (optionally O);

n is an integer, optionally from 1 to 200 (optionally from 5 to 150, and optionally from 40 to 70), although higher values of n are also contemplated; and

each of R₁, R₂, R₃, R₄, and R₅ is independently selected from the group consisting of hydrogen, alkyl, cycloalkyl, alkenyl, alkynyl, alkoxy, hydroxy, oxo, thiol and thioalkoxy.

In some embodiments, n is at least 5, optionally at least 8, optionally at least 15, optionally at least 25, and optionally at least 40.

In some embodiments, n is no more than 200, optionally no more than 150, and optionally no more than 70.

The poly(ethylene glycol) or analog thereof may optionally comprise a copolymer, for example, wherein the CR₁R₂—CR₃R₄—Y units in the above formula are not all identical to one another.

In some embodiments, at least 50% of CR₁R₂—CR₃R₄—Y units are identical. Optionally, at least 70%, optionally at least 90%, and optionally 100% of the CR₁R₂—CR₃R₄—Y units are identical.

Optionally, the linking moiety is branched, for example, such that for one or more CR₁R₂—CR₃R₄—Y units in the above formula, at least of one of R₁, R₂, R₃, R₄, and R₅ is —(CR₁R₂—CR₃R₄—Y)_(p)—X₃—, wherein R₁-R₄ and Y are as defined hereinabove, p is an integer as defined herein for n (e.g., from 1 to 200), and X₃ is as defined herein for X₁ and X₂.

The functional groups may optionally form a bond such as, but not limited to, an amide bond, an amide bond, an ester bond, and/or an ether bond.

For example, the functional group may optionally comprise a carbonyl group which forms an amide bond with a nitrogen atom in a polypeptide (e.g., in a lysine residue or N-terminus), or an ester bond with an oxygen atom in a polypeptide (e.g., in a serine, threonine or tyrosine residue).

Alternatively or additionally, the functional group may optionally comprise a heteroatom (e.g., N, S, O) which forms an amide bond, ester bond or thioester bond with a carbonyl group in a polypeptide (e.g., in a glutamate or aspartate residue or in a C-terminus).

Alternative or additionally, the functional group may comprise an alkyl or aryl group attached to a polypeptide (e.g., to a heteroatom in the polypeptide).

Alternatively or additionally, the functional group may optionally comprise a nitrogen atom which forms an amine bond with an alkyl group in an α-galactosidase monomer, or an α-galactosidase monomermay optionally comprise a nitrogen atom which forms an amine bond with an alkyl group in the functional group. Such an amine bond may be formed by reductive amination (e.g., as described hereinbelow).

In some embodiments, at least one of the functional groups forms an amide bond with a polypeptide (e.g., with a lysine residue therein).

The functional groups may be identical to one another or different.

In some embodiments, at least one of the functional groups is attached to one functionality of a polypeptide (e.g., an amine group of a lysine residue or N-terminus), and at least one of the functional groups is attached to a different functionality of a polypeptide (e.g., a thiol group of a cysteine residue).

According to optional embodiments, the multimeric protein structure described herein exhibits a high stability in human plasma conditions and/or in lysosomal conditions.

As used herein, the phrase “human plasma conditions” refers to human plasma as a medium, at a temperature of 37° C.

As used herein, the phrase “lysosomal conditions” refers to an aqueous solution having a pH of 4.6 as a medium (e.g., a citrate phosphate buffer described herein), at a temperature of 37° C.

Enhanced stability under lysosomal conditions is advantageous because the lysosome is a target for replacement therapy for α-galactosidase, as lysosomes are the normal location for α-galactosidase activity in a body, and lysosomal conditions (e.g., acidic pH) represent optimal conditions for activity of α-galactosidase.

Without being bound by any particular theory, it is believed that enhanced stability in serum-like conditions (e.g., the human plasma conditions described herein) is also advantageous because stable α-galactosidase in the blood can act on metabolites (e.g., Gb₃) present in the blood due to efflux from cells. A serum-active multimeric protein structure could optionally be efficient in removing and preventing glycosphinglipids deposited within blood vessel walls which promote inflammation [Bodary et al., TCM 17(4):129-133]. For example, in Fabry disease, the major pathogenesis results from the accumulation of Gb₃ in the vascular endothelium, leading to vascular occlusion of small vessels, ischemia and infarction of these vessels and ischemia and infarction of the kidney, heart and brain [Desnick et al., 2003, Annals of Internal Medicine, 138(4):338-346]. Additionally, enhanced stability in serum can negate the need for lysosomal trafficking. ERT can thereby become much more accessible, as robust cost-effective host systems e.g., plants, can be employed.

According to optional embodiments, the high stability of the multimeric protein structure in human plasma conditions is such that the multimeric protein structure exhibits, upon being subjected to human plasma conditions for one hour, an α-galactosidase activity which is at least 10% higher, optionally 20% higher, optionally 50% higher, and optionally 100% higher, than an α-galactosidase activity of native α-galactosidase upon subjecting the native α-galactosidase to the human plasma conditions for one hour.

Alternatively or additionally, the high stability of the multimeric protein structure in human plasma conditions is such that an α-galactosidase activity of the multimeric protein structure decreases more slowly in human plasma conditions than a corresponding activity of the native α-galactosidase. Optionally, the multimeric protein structure exhibits an activity which decreases upon subjecting the protein structure to human plasma conditions for one hour by a percentage which is at least 10% less, optionally 20% less, optionally 50% less, and optionally 80% less, than the percentage by which a corresponding activity of the native α-galactosidase decreases upon subjecting the native α-galactosidase to human plasma conditions for one hour.

It is to be understood that herein, a decrease which is “10% less” than a decrease of 50% refers to a decrease of 45% (45 being 10% less than 50), and not to a decrease of 40% (50%-10%).

Alternatively or additionally, the high stability of the multimeric protein structure in human plasma conditions is such that an α-galactosidase activity of the multimeric protein structure remains substantially unchanged upon subjecting the multimeric protein structure to human plasma conditions for one hour, and optionally for 2, 4 or even 6 hours.

As used herein, the phrase “substantially unchanged” refers to a level (e.g., of activity) which remains in a range of from 50% to 150% of the initial level, and optionally a level which remains at least 60%, optionally at least 70%, optionally at least 80%, and optionally at least 90% of the initial level.

Optionally, the high stability of the multimeric protein structure in lysosomal conditions is such that the multimeric protein structure exhibits, upon being subjected to lysosomal conditions for a predetermined time period (e.g., one day, two days, 3 days, one week), an α-galactosidase activity which is at least 10% higher, optionally 20% higher, optionally 50% higher, and optionally 100% higher, than an activity of native α-galactosidase upon subjecting the native α-galactosidase to the lysosomal conditions for the same predetermined time period.

Alternatively or additionally, the high stability of the multimeric protein structure in lysosomal conditions is such that an α-galactosidase activity of the multimeric protein structure decreases more slowly in lysosomal conditions than a corresponding activity of the native α-galactosidase. Optionally, the multimeric protein structure exhibits an activity which decreases upon subjecting the protein structure to lysosomal conditions for a predetermined time period (e.g., one day, 2 days, 3 days, one week), by a percentage which is at least 10% less, optionally 20% less, optionally 50% less, and optionally 80% less, than the percentage by which a corresponding activity of the native α-galactosidase decreases upon subjecting the native α-galactosidase to lysosomal conditions for the same time period.

Alternatively or additionally, the high stability of the multimeric protein structure in lysosomal conditions is such that an α-galactosidase activity of the multimeric protein structure remains substantially unchanged upon subjecting the multimeric protein structure to lysosomal conditions for one day, for 2 days, for 3 days, for one week, for two weeks, and/or for one month.

As exemplified in the Examples section herein, in addition to exhibiting more stability over time, the multimeric protein structure may exhibit parameters of α-galactosidase activity which are different than those of the native α-galactosidase.

Hence, according to optional embodiments, the multimeric protein structure is characterized as exhibiting, independently of any decay of activity over time, an α-galactosidase activity which is higher than an α-galactosidase activity of a native form of the protein. Optionally, the activity is 10% higher, and optionally 20% higher, than the corresponding activity of the native form.

In order to characterize such an activity, the activity is preferably determined immediately (e.g., within 1 hour, within 15 minutes) upon subjecting the native α-galactosidase or multimeric protein structure to conditions (e.g., as described herein) in which the activity decreases substantially, so that the measured activity will reflect the activity per se, and not a degree of stability.

Optionally, the multimeric protein structure is characterized as exhibiting an α-galactosidase activity in lysosomal conditions which is higher than a corresponding activity of native α-galactosidase.

Alternatively or additionally, the multimeric protein structure is characterized as exhibiting an α-galactosidase activity in simulated physiological conditions at a neutral pH which is higher than a corresponding activity of native α-galactosidase. The simulated physiological conditions comprise an aqueous solution (e.g., phosphate buffer saline) at a temperature of 37° C. The pH is optionally 7. Alternatively, the pH is 7.4.

The α-galactosidase activity described herein is a biological activity which is characteristic of α-galactosidase (e.g., a catalytic activity characteristic of α-galactosidase, such as hydrolysis of a terminal α-galactosyl moiety of a substrate).

In some embodiments, a catalytic activity of α-galactosidase is characterized by a rate of catalysis at saturation (i.e., a V_(max) value).

Alternatively, the α-galactosidase activity is a therapeutic activity (e.g., an enzymatic activity having a therapeutic effect), such as a therapeutic activity in the context of Fabry disease. Optionally, the therapeutic activity is determined in experimental animals (e.g., Fabry mice), and optionally in human Fabry patients.

Techniques for determining an activity of α-galactosidase will be known to a skilled person. Typically, the α-galactosidase (i.e., the native form or a multimeric protein structure described herein) is contacted with a compound recognized in the art as a substrate of α-galactosidase, and the degree of activity is then determined quantitatively. Compounds which allow for particularly convenient detection of α-galactosidase activity are known in the art and are commercially available.

In some embodiments, α-galactosidase activity is determined by assaying hydrolysis of 4-methylumbelliferyl-α-D-galactopyranoside (e.g., as described in the Examples section herein).

In some embodiments, α-galactosidase activity is determined by assaying hydrolysis of p-nitrophenyl-α-D-galactopyranoside (e.g., as described in the Examples section herein).

When comparing an activity of a multimeric protein structure described herein with an activity of native α-galactosidase, the native α-galactosidase preferably comprises α-galactosidase monomers substantially identical (e.g., with respect to amino acid sequence and glycosylation pattern) to the α-galactosidase monomers of the multimeric structure.

According to some embodiments, the multimeric protein structure is characterized by a circulating half-life in a physiological system (e.g., blood, serum and/or plasma of a human or laboratory animal) which is higher (e.g., at least 20%, at least 50% higher, at least 100% higher, at least 400% higher, at least 900% higher) than a circulating half-life of native α-galactosidase.

An increased circulating half-life may optionally be associated with a higher in vitro stability (e.g, as described herein), a higher in vivo stability (e.g, resistance to metabolism) and/or with other factors (e.g., reduced renal clearance).

Circulating half-lives can be determined by taking samples (e.g., blood samples, tissue samples) from physiological systems (e.g., humans, laboratory animals) at various intervals, and determining a level of α-galactosidase in the sample, using techniques known in the art.

Optionally, the half-life is calculated as a terminal half-life (e.g., as described in the Examples section), wherein half-life is the time required for a concentration (e.g., a blood concentration) to decrease by 50% after pseudo-equilibrium of distribution has been reached. The terminal half-life may be calculated from a terminal linear portion of a time vs. log concentration, by linear regression of time vs. log concentration (see, for example, Toutain & Bousquet-Melou [J Vet Pharmacol Ther 2004, 27:427-39]). Thus, the terminal half-life is a measure of the decrease in drug plasma concentration due to drug elimination and not of decreases due to other reasons, and is not necessarily the time necessary for the amount of the administered drug to fall by one half.

Determining a level of α-galactosidase (e.g., the multimeric protein structure or the native α-galactosidase) may comprise detecting the physical presence of α-galactosidase (e.g., via an antibody against α-galactosidase) and/or detecting a level of an α-galactosidase activity (e.g., as described herein).

According to some embodiments, the multimeric protein structure is characterized by an α-galactosidase activity in an organ (e.g., spleen, heart, kidney, brain, liver) upon administration (e.g., intravenous administration) of the protein structure to a vertebrate (e.g., a human, a mouse), for example, a vertebrate with an α-galactosidase deficiency (e.g., a human Fabry disease patient, a Fabry mouse). Optionally, the α-galactosidase activity in the organ is higher than an α-galactosidase activity of native α-galactosidase in the organ, upon an equivalent administration to a vertebrate.

The activity in an organ may be a function of uptake of the α-galactosidase and/or retention of α-galactosidase activity following uptake.

Optionally, α-galactosidase activity in the organ is determined 2 hours after administration, and optionally 24 hours, optionally 3 days, optionally 7 days, and optionally 14 days, after administration.

As increased activity of α-galactosidase in a liver may in some cases be associated with a lower activity in other parts of a body, and hence, with a reduced biological effect of the α-galactosidase.

Hence, in some embodiments, the multimeric protein structure is characterized by an enhanced α-galactosidase activity in an organ other than a liver. Exemplary organs include the spleen, heart and kidneys.

In some embodiments, the multimeric protein structure is characterized by an enhanced α-galactosidase activity in an organ after administration (as described herein) which is at least 20% higher, optionally at least 50% higher, optionally at least 100% higher, and optionally at least 300% higher, than the activity of native α-galactosidase after an equivalent administration. As noted hereinabove, the present inventors have devised and successfully prepared and practiced stabilized forms of α-galactosidase by means of multimeric structures of cross-linked α-galactosidase monomers.

Optionally, the α-galactosidase is a human α-galactosidase (e.g., a recombinant human α-galactosidase), for example, in order to facilitate optimal biocompatibility for administration to human subjects. Human α-galactosidase is commercially available, for example, as Replagal® (agalsidase alpha, Shire) and Fabrazyme® (agalsidase beta, Genzyme).

Herein, “human α-galactosidase” refers to an α-galactosidase comprising an amino acid sequence substantially identical (e.g., as described hereinabove) to an amino acid sequence of an α-galactosidase protein which naturally occurs in humans

In some embodiments, the α-galactosidase is a plant recombinant α-galactosidase. Exemplary α-galactosidases include plant recombinant human α-galactosidases.

Examples of α-GAL include, without limitation, α-GAL having an amino acid sequence selected from the group consisting of SEQ ID NO: 1, SEQ ID NO: 2, and SEQ ID NO: 3. Optionally, the α-GAL has an amino acid sequence selected from the group consisting of SEQ ID NO: 2 and SEQ ID NO: 3.

As used herein, “α-galactosidase” refers to any protein which exhibits an enzymatic activity (e.g., hydrolysis) towards galactose moieties in Gb₃ (e.g., α-galactosidase A). Optionally, “α-galactosidase” refers to E.C. 3.2.1.22.

The α-galactosidase of embodiments of the invention can be purified (e.g., from plants or animal tissue) or generated by recombinant DNA technology.

As described herein, activity of α-galactosidase in serum may be highly advantageous, for example, for reducing Gb₃ levels in serum.

Hence, in some embodiments, the α-galactosidase is an alkaline α-galactosidase.

As used herein the phrase “alkaline α-galactosidase” refers to α-GAL characterized by an ability to hydrolyse terminal-linked α-galactose moieties from galactose-containing oligosaccharides under neutral to basic pH conditions (e.g., about pH 7-7.5), particularly at a normal serum pH (e.g., about 7.35-7.45).

It will be appreciated that an alkaline α-GAL of some embodiments of the invention may be active under neutral to basic pH conditions but may still display activity under acidic pH conditions (i.e., about 4.6).

In a specific embodiment the enzyme is active under acidic to basic pH conditions (i.e., about pH 4.2-7.5).

In yet another specific embodiment the enzyme is active under pH of about 6.5-7.5.

Specific examples of alkaline α-galactosidases which can be used in accordance with the present teachings are provided in US Patent Application 20070036883, WO03/097791, and in PCT/IL2010/000956, each of which is hereby incorporated by reference in its entirety.

Thus, alkaline α-galactosidase can be a member of the plant family selected from the group consisting of Cucurbitaceae, Lamiaceae, Piperaceae, Solanaceae, Leguminosae, Cruciferae and Gramineae families

According to a specific embodiment, the alkaline α-galactosidase is from melon.

P.-R. Gaudreault and J. A. Webb have described in several publications, (such as “Alkaline alpha-galactosidase in leaves of Cucurbita pepo”, Plant Sci. Lett. 24, 281-288, 1982, “Partial purification and properties of an alkaline alpha-galactosidase from mature leaves of Cucurbita pepo”, Plant Physiol., 71, 662-668, 1983, and “Alkaline alpha-galactosidase activity and galactose metabolism in the family Cucurbitaceae”, Plant Science, 45, 71-75, 1986), a novel α-galactosidase purified from young leaves of Cucurbita pepo, that has an optimal activity at alkaline conditions (pH 7.5). In addition to the alkaline α-galactosidase, they also reported three acid forms of the enzyme, and distinct substrate preferences were found for the acid and alkaline forms

α-Galactosidase activity at alkaline pH has been observed in other cucurbit tissue, such as cucumber fruit pedicels, young squash fruit and young melon fruit (“Melons: Biochemical and Physiological Control of Sugar Accumulation”, In: Encyclopedia of Agricultural Science, vol. 3, pp. 25-37, Arntzen, C. J., et al., eds. Academic Press, New York, 1994).

Bachmann et al. (“Metabolism of the raffinose family oligosaccharides in leaves of Ajuga reptens L.”, Plant Physiology 105:1335-1345, 1994) that Ajuga reptens plants (common bugle), a stachyose translocator from the unrelated Lamiaceae family also contains an alkaline α-galactosidase. This enzyme was partially characterized and found to have high affinity to stachyose. Also, leaves of the Peperomia camptotricha L. plant, from the family Piperaceae, show α-galactosidase activity at alkaline pH, suggesting that they also contain an alkaline α-galactosidase enzyme (Madore, M., “Catabolism of raffinose family oligosaccharides by vegetative sink tissues”, In: Carbon Partitioning and Source-Sink Interactions in Plants, Madore, M. and Lucas, W. J. (eds.) pp. 204-214, 1995, American Society of Plant Physiologists, Maryland). Similarly, Gao and Schaffer (Plant Physiol. 1999; 119:979-88, which is incorporated fully herein by reference) have reported an α-galactosidase activity with alkaline pH optimum in crude extracts of tissues from a variety of species including members of the Cucurbit and Coleus (Lamiaceae) families.

Specific examples of plant alkaline α-galactosidase sequences are provided in SEQ ID NOs: 4, 5 and 13 (Cucumis melo), 6 (T. tetragonioides), 7 and 12 (Cucumis sativus), 8 and 9 (Zea mays), 10 (Oruza sativa), 11 (Pisum sativum) and 14 (Coffea arabica).

In some embodiments, the α-galactosidase is an acid α-galactosidase.

As used herein, “acid α-galactosidase” refers to α-galactosidase characterized by an ability to hydrolyse terminal-linked α-galactose moieties from galactose-containing oligosaccharides under acidic pH conditions (e.g., about pH 4.2-5), such as occur in a lysosome.

The α-galactosidase of embodiments of the invention can be of any human, animal or plant source, provided no excessively adverse immunological reaction is induced upon in vivo administration (e.g., plant to human).

To reduce immunological reaction, a non-human α-galactosidase preparation (e.g., of plant α-galactosidase) can be co-administered with a human α-galactosidase (i.e., acid human α-galactosidase).

Optionally, the multimeric protein structure further comprises at least one mannose-6-phosphate (M6P) moiety. The M6P moiety (or moieties) may be linked to one or more of the α-galactosidase monomers of the multimeric protein structure (e.g., via a linker).

Techniques and reagents for introducing M6P-containing moieties to a biomolecule (e.g., a polypeptide) are described in WO 2009/024977.

As exemplified in the Examples section herein, a multimeric protein structure described herein may be conveniently prepared by reacting α-galactosidase with a cross-linking agent.

Hence, according to another aspect of embodiments of the invention, there is provided a process of preparing a multimeric protein structure described herein. The process comprises reacting α-galactosidase, so as to introduce at least one linking moiety which covalently links at least two α-galactosidase monomers.

Optionally, the linking moiety is a bond (e.g., an amide bond, a disulfide bond) which links one α-galactosidase monomer to another α-galactosidase monomer. Optionally, the bond is introduced by using suitable conditions and/or reagents. For example, reagents which are suitable for forming an amide bond from a carboxylic acid group and an amine group are known in the art.

Optionally, the linking moiety is a moiety which is not derived from a part of the α-galactosidase. For example, the linking moiety may be an oligomer, a polymer, a residue of a small molecule (e.g., an amino acid).

In some embodiments, the linking moiety is introduced by reacting the α-galactosidase with a cross-linking agent which comprises the linking moiety (e.g., as described herein) and at least two reactive groups.

Optionally, the α-galactosidase is reacted under conditions in which the native α-galactosidase is in a dimeric form.

In some embodiments, the cross-linking agent is reacted with the α-galactosidase at a molar ratio in a range of from 5:1 to 500:1 (cross-linking agent: α-galactosidase monomer), optionally in a range of from 50:1 to 400:1, and optionally in a range of from 75:1 to 300:1 (e.g., about 100:1, about 200:1).

The process optionally further comprises purifying the cross-linked protein, for example, removing excess cross-linking agent. Common purification methods may be used, such as dialysis and/or ultra-filtration using appropriate cut-off membranes and/or additional chromatographic steps, including size exclusion chromatography, ion exchange chromatography, affinity chromatography, hydrophobic interaction chromatography, and the like.

The reactive group is selected suitable for undergoing a chemical reaction that leads to a bond formation with a complementary functionality in the α-galactosidase monomer. Optionally, each reactive group is capable of forming a covalent bond between the linking moiety described herein and at least one polypeptide (e.g., so as to form a functional group bound to the polypeptide, as described herein).

The reactive groups of a cross-linking agent may be identical to one another or different.

As used herein, the phrase “reactive group” describes a chemical group that is capable of undergoing a chemical reaction that typically leads to a bond formation. The bond, according to the present embodiments, is preferably a covalent bond (e.g., for each of the reactive groups). Chemical reactions that lead to a bond formation include, for example, nucleophilic and electrophilic substitutions, nucleophilic and electrophilic addition reactions, alkylations, addition-elimination reactions, cycloaddition reactions, rearrangement reactions and any other known organic reactions that involve a functional group, as well as combinations thereof.

The reactive group may optionally comprise a non-reactive portion (e.g., an alkyl) which may serve, for example, to attach a reactive portion of the reactive group to a linking moiety (e.g., poly(alkylene glycol) or analog thereof) described herein.

The reactive group is preferably selected so as to enable its conjugation to α-galactosidase. Exemplary reactive groups include, but are not limited to, carboxylate (e.g., —CO₂H), thiol (—SH), amine (—NH₂), halo, azide (—N₃), isocyanate (—NCO), isothiocyanate (—N═C═S), hydroxy (—OH), carbonyl (e.g., aldehyde), maleimide, sulfate, phosphate, sulfonyl (e.g. mesyl, tosyl), etc. as well as activated groups, such as N-hydroxysuccinimide (NHS) (e.g. NHS esters), sulfo-N-hydroxysuccinimide, anhydride, acyl halide (—C(═O)-halogen) etc.

In some embodiments, the reactive group comprises a leaving group, such as a leaving group susceptible to nucleophilic substitution (e.g., halo, sulfate, phosphate, carboxylate, N-hydroxysuccinimide).

Optionally, the reactive group may be in an activated form thereof.

As used herein, the phrase “activated form” describes a derivative of a chemical group (e.g., a reactive group) which is more reactive than the chemical group, and which is thus readily capable of undergoing a chemical reaction that leads to a bond formation. The activated form may comprise a particularly suitable leaving group, thereby facilitating substitution reactions. For example, a —C(═O)—NHS group (N-hydroxysuccinimide ester, or —C(═O)—O-succinimide) is a well-known activated form of —C(═O)OH, as NHS (N-hydroxysuccinimide) can be reacted with a —C(═O)OH to form —C(═O)—NHS, which readily reacts to form products characteristic of reactions involving —C(═O)OH groups, such as amides and esters.

The reactive group can be attached to the rest of the linking moiety (e.g., a poly(alkylene glycol) or analog thereof) via different groups, atoms or bonds. These may include an ether bond [e.g., —O-alkyl-], an ester bond [e.g., —O—C(═O)-alkyl-], a carbamate [e.g., O—C(═O)—NH-alkyl-], etc. Thus, a variety of terminal groups can be employed.

The following are non-limiting examples of the different groups that may constitute a reactive group as described herein: —CH₂CO₂H, —CH₂CH₂CO₂H, —CH₂CH₂SH, —CH₂CH₂NH₂, —CH₂CH₂N₃, —CH₂CH₂NCO, —CH₂—C(═O)—NHS, —CH₂CH₂—C(═O)—NHS, —C(═O)—CH₂—C(═O)—NHS, —CH₂CH₂—NHC(═O)CH₂CH₂— maleimide, etc.

The number of methylene groups in each of the above reactive groups is merely exemplary, and may be varied.

The reactive group may also comprise the heteroatom at the end of a poly(alkylene glycol) chain (e.g., —OH).

In exemplary embodiments of the present invention, the reactive group comprises a carboxylate (e.g., an activated carboxylate such as an N-hydroxysuccinimide ester).

Optionally, the reactive group reacts with an amine group in the α-galactosidase (e.g., in a lysine residue and/or an N-terminus) to form an amide bond.

In some embodiments, the reaction of the reactive group comprises reductive amination, wherein an amine group reacts with an aldehyde group to form an imine, and the imine is reduced (e.g., by addition of a reducing agent, such as sodium cyanoborohydride) to form an amine bond. The reactive group may be an amine group which reacts with an aldehyde group of the α-galactosidase (e.g., on a saccharide moiety attached to the polypeptide of the protein), or the reactive group may be an aldehyde group which reacts with an amine group of the α-galactosidase (e.g., on a lysine residue). Optionally, a saccharide moiety of α-galactosidase is oxidized by an oxidizing agent to form an aldehyde group, prior to reaction of the reactive group with the α-galactosidase. For example, reaction of a saccharide with sodium periodate may be used to produce a pair of aldehyde groups in a saccharide moiety.

In some embodiments, at least one of the reactive groups is selected so as to react with one functionality of an α-galactosidase monomer (e.g., an amine group of a lysine residue or N-terminus), and at least one of the reactive groups is selected so as to react with a different functionality of an α-galactosidase monomer (e.g., a thiol group of a cysteine residue).

Optionally, one or more polypeptides described herein are reacted with a glycosylation reagent for introducing one or more M6P moieties, in order to obtain an M6P-containing multimeric protein structure (e.g., as described herein). Suitable M6P-containing glycosylation reagents and their use are described, for example, in WO 2009/024977.

As used herein, the terms “amine” and “amino” refer to either a —NR′R″ group, wherein R′ and R″ are selected from the group consisting of hydrogen, alkyl, cycloalkyl, heteroalicyclic (bonded through a ring carbon), aryl and heteroaryl (bonded through a ring carbon). R′ and R″ are bound via a carbon atom thereof. Optionally, R′ and R″ are selected from the group consisting of hydrogen and alkyl comprising 1 to 4 carbon atoms. Optionally, R′ and R″ are hydrogen.

As used herein throughout, the term “alkyl” refers to a saturated aliphatic hydrocarbon including straight chain and branched chain groups. Preferably, the alkyl group has 1 to 20 carbon atoms. Whenever a numerical range; e.g., “1-20”, is stated herein, it implies that the group, in this case the alkyl group, may contain 1 carbon atom, 2 carbon atoms, 3 carbon atoms, etc., up to and including 20 carbon atoms. More preferably, the alkyl is a medium size alkyl having 1 to 10 carbon atoms. Most preferably, unless otherwise indicated, the alkyl is a lower alkyl having 1 to 4 carbon atoms. The alkyl group may be substituted or unsubstituted. When substituted, the substituent group can be, for example, cycloalkyl, alkenyl, alkynyl, aryl, heteroaryl, heteroalicyclic, halo, hydroxy, alkoxy, aryloxy, thiohydroxy, thioalkoxy, thioaryloxy, sulfinyl, sulfonyl, cyano, nitro, azide, phosphonyl, phosphinyl, oxo, carbonyl, thiocarbonyl, urea, thiourea, O-carbamyl, N-carbamyl, O-thiocarbamyl, N-thiocarbamyl, C-amido, N-amido, C-carboxy, O-carboxy, sulfonamido, and amino, as these terms are defined herein.

A “cycloalkyl” group refers to an all-carbon monocyclic or fused ring (i.e., rings which share an adjacent pair of carbon atoms) group wherein one of more of the rings does not have a completely conjugated pi-electron system. Examples, without limitation, of cycloalkyl groups are cyclopropane, cyclobutane, cyclopentane, cyclopentene, cyclohexane, cyclohexadiene, cycloheptane, cycloheptatriene, and adamantane. A cycloalkyl group may be substituted or unsubstituted. When substituted, the substituent group can be, for example, alkyl, alkenyl, alkynyl, aryl, heteroaryl, heteroalicyclic, halo, hydroxy, alkoxy, aryloxy, thiohydroxy, thioalkoxy, thioaryloxy, sulfinyl, sulfonyl, cyano, nitro, azide, phosphonyl, phosphinyl, oxo, carbonyl, thiocarbonyl, urea, thiourea, O-carbamyl, N-carbamyl, O-thiocarbamyl, N-thiocarbamyl, C-amido, N-amido, C-carboxy, O-carboxy, sulfonamido, and amino, as these terms are defined herein.

An “alkenyl” group refers to an alkyl group which consists of at least two carbon atoms and at least one carbon-carbon double bond.

An “alkynyl” group refers to an alkyl group which consists of at least two carbon atoms and at least one carbon-carbon triple bond.

An “aryl” group refers to an all-carbon monocyclic or fused-ring polycyclic (i.e., rings which share adjacent pairs of carbon atoms) groups having a completely conjugated pi-electron system. Examples, without limitation, of aryl groups are phenyl, naphthalenyl and anthracenyl. The aryl group may be substituted or unsubstituted. When substituted, the substituent group can be, for example, alkyl, alkenyl, alkynyl, cycloalkyl, aryl, heteroaryl, heteroalicyclic, halo, hydroxy, alkoxy, aryloxy, thiohydroxy, thioalkoxy, thioaryloxy, sulfinyl, sulfonyl, cyano, nitro, azide, phosphonyl, phosphinyl, oxo, carbonyl, thiocarbonyl, urea, thiourea, O-carbamyl, N-carbamyl, O-thiocarbamyl, N-thiocarbamyl, C-amido, N-amido, C-carboxy, O-carboxy, sulfonamido, and amino, as these terms are defined herein.

A “heteroaryl” group refers to a monocyclic or fused ring (i.e., rings which share an adjacent pair of atoms) group having in the ring(s) one or more atoms, such as, for example, nitrogen, oxygen and sulfur and, in addition, having a completely conjugated pi-electron system. Examples, without limitation, of heteroaryl groups include pyrrole, furane, thiophene, imidazole, oxazole, thiazole, pyrazole, pyridine, pyrimidine, quinoline, isoquinoline and purine. The heteroaryl group may be substituted or unsubstituted. When substituted, the substituent group can be, for example, alkyl, alkenyl, alkynyl, cycloalkyl, aryl, heteroaryl, heteroalicyclic, halo, hydroxy, alkoxy, aryloxy, thiohydroxy, thioalkoxy, thioaryloxy, sulfinyl, sulfonyl, cyano, nitro, azide, phosphonyl, phosphinyl, oxo, carbonyl, thiocarbonyl, urea, thiourea, O-carbamyl, N-carbamyl, O-thiocarbamyl, N-thiocarbamyl, C-amido, N-amido, C-carboxy, O-carboxy, sulfonamido, and amino, as these terms are defined herein.

A “heteroalicyclic” group refers to a monocyclic or fused ring group having in the ring(s) one or more atoms such as nitrogen, oxygen and sulfur. The rings may also have one or more double bonds. However, the rings do not have a completely conjugated pi-electron system. The heteroalicyclic may be substituted or unsubstituted. When substituted, the substituted group can be, for example, lone pair electrons, alkyl, alkenyl, alkynyl, cycloalkyl, aryl, heteroaryl, heteroalicyclic, halo, hydroxy, alkoxy, aryloxy, thiohydroxy, thioalkoxy, thioaryloxy, sulfinyl, sulfonyl, cyano, nitro, azide, phosphonyl, phosphinyl, oxo, carbonyl, thiocarbonyl, urea, thiourea, O-carbamyl, N-carbamyl, O-thiocarbamyl, N-thiocarbamyl, C-amido, N-amido, C-carboxy, O-carboxy, sulfonamido, and amino, as these terms are defined herein. Representative examples are piperidine, piperazine, tetrahydrofuran, tetrahydropyran, morpholine and the like.

A “hydroxy” group refers to an —OH group.

An “azide” group refers to a —N═N⁺═N⁻ group.

An “alkoxy” group refers to both an —O-alkyl and an —O-cycloalkyl group, as defined herein.

An “aryloxy” group refers to both an —O-aryl and an —O-heteroaryl group, as defined herein.

An “ether” refers to both an alkoxy and an aryloxy group, wherein the group is linked to an alkyl, alkenyl, alkynyl, cycloalkyl, aryl, heteroaryl or heteroalicyclic group.

An ether bond describes a —O— bond.

A “thiohydroxy” or “thiol” group refers to a —SH group.

A “thioalkoxy” group refers to both an —S-alkyl group, and an —S-cycloalkyl group, as defined herein.

A “thioaryloxy” group refers to both an —S-aryl and an —S-heteroaryl group, as defined herein.

A “thioether” refers to both a thioalkoxy and a thioaryloxy group, wherein the group is linked to an alkyl, alkenyl, alkynyl, cycloalkyl, aryl, heteroaryl or heteroalicyclic group.

A thioether bond describes a —S— bond.

A “disulfide” group refers to both a —S-thioalkoxy and a —S-thioaryloxy group.

A disulfide bond describes a —S—S— bond.

A “carbonyl” group refers to a —C(═O)—R′ group, where R′ is defined as hereinabove.

A “thiocarbonyl” group refers to a —C(═S)—R′ group, where R′ is as defined herein.

A “carboxyl” refers to both “C-carboxy” and O-carboxy”.

A “C-carboxy” group refers to a —C(═O)—O—R′ groups, where R′ is as defined herein.

An “O-carboxy” group refers to an R′C(═O)—O— group, where R′ is as defined herein.

An “oxo” group refers to a ═O group.

A “carboxylate” or “carboxyl” encompasses both C-carboxy and O-carboxy groups, as defined herein.

A “carboxylic acid” group refers to a C-carboxy group in which R′ is hydrogen.

A “thiocarboxy” or “thiocarboxylate” group refers to both —C(═S)—O—R′ and —O—C(═S)R′ groups.

An “ester” refers to a C-carboxy group wherein R′ is not hydrogen.

An ester bond refers to a —O—C(═O)— bond.

A thioester bond refers to a —O—C(═S)— bond or to a —S—C(═O) bond.

A “halo” group refers to fluorine, chlorine, bromine or iodine.

A “sulfinyl” group refers to an —S(═O)—R′ group, where R′ is as defined herein.

A “sulfonyl” group refers to an —S(═O)₂—R′ group, where R′ is as defined herein.

A “sulfonate” group refers to an —S(═O)₂—O—R′ group, where R′ is as defined herein.

A “sulfate” group refers to an —O—S(═O)₂—O—R′ group, where R′ is as defined as herein.

A “sulfonamide” or “sulfonamido” group encompasses both S-sulfonamido and N-sulfonamido groups, as defined herein.

An “S-sulfonamido” group refers to a —S(═O)₂—NR′R″ group, with each of R′ and R″ as defined herein.

An “N-sulfonamido” group refers to an R′S(═O)₂—NR″ group, where each of R′ and R″ is as defined herein.

An “O-carbamyl” group refers to an —OC(═O)—NR′R″ group, where each of R′ and R″ is as defined herein.

An “N-carbamyl” group refers to an R′OC(═O)—NR″— group, where each of R′ and R″ is as defined herein.

A “carbamyl” or “carbamate” group encompasses O-carbamyl and N-carbamyl groups.

A carbamate bond describes a —O—C(═O)—NR′— bond, where R is as described herein.

An “O-thiocarbamyl” group refers to an —OC(═S)—NR′R″ group, where each of R′ and R″ is as defined herein.

An “N-thiocarbamyl” group refers to an R′OC(=S)NR″— group, where each of R′ and R″ is as defined herein.

A “thiocarbamyl” or “thiocarbamate” group encompasses O-thiocarbamyl and N-thiocarbamyl groups.

A thiocarbamate bond describes a —O—C(═S)—NR— bond, where R is as described herein.

A “C-amido” group refers to a —C(═O)—NR′R″ group, where each of R′ and R″ is as defined herein.

An “N-amido” group refers to an R′C(═O)—NR″— group, where each of R′ and R″ is as defined herein.

An “amide” group encompasses both C-amido and N-amido groups.

An amide bond describes a —NR—C(═O)— bond, where R is as defined herein.

An amine bond describes a bond between a nitrogen atom in an amine group (as defined herein) and an R′ group in the amine group.

A thioamide bond describes a —NR—C(═S)— bond, where R′ is as defined herein.

A “urea” group refers to an —N(R′)—C(═O)—NR″R′″ group, where each of R′ and R″ is as defined herein, and R″' is defined as R′ and R″ are defined herein.

A “nitro” group refers to an —NO₂ group.

A “cyano” group refers to a —C≡N group.

The term “phosphonyl” or “phosphonate” describes a —P(═O)(OR′)(OR″) group, with R′ and R″ as defined hereinabove.

The term “phosphate” describes an —O—P(═O)(OR′)(OR″) group, with each of R′ and R″ as defined hereinabove.

A “phosphoric acid” is a phosphate group is which each of R is hydrogen.

The term “phosphinyl” describes a —PR′R″ group, with each of R′ and R″ as defined hereinabove.

The term “thiourea” describes a —N(R′)—C(═S)—NR″— group, with each of R′ and R″ as defined hereinabove.

As described herein, multimeric protein structures described herein may exhibit improved stability and stronger and/or longer lasting α-galactosidase activity at therapeutically important sites in vivo. Such multimeric protein structures are therefore highly beneficial for use in various medical applications in which α-galactosidase activity is desirable, including therapeutic and research applications.

Hence, according to some embodiments, the multimeric protein structure described herein is for use as a medicament, for example, a medicament for treating Fabry disease.

According to another aspect of embodiments of the invention, there is provided a method of treating Fabry disease, the method comprising administering to a subject in need thereof a therapeutically effective amount of a multimeric protein structure described herein.

According to another aspect of embodiments of the invention, there is provided a pharmaceutical composition that comprises a multimeric protein structure as described herein and a pharmaceutically acceptable carrier.

As used herein a “pharmaceutical composition” refers to a preparation of one or more of the multimeric protein structures described herein, with other chemical components such as pharmaceutically acceptable and suitable carriers and excipients. The purpose of a pharmaceutical composition is to facilitate administration of a compound to an organism.

Hereinafter, the term “pharmaceutically acceptable carrier” refers to a carrier or a diluent that does not cause significant irritation to an organism and does not abrogate the biological activity and properties of the administered compound. Examples, without limitations, of carriers are: propylene glycol, saline, emulsions and mixtures of organic solvents with water, as well as solid (e.g., powdered) and gaseous carriers.

Herein the term “excipient” refers to an inert substance added to a pharmaceutical composition to further facilitate administration of a compound. Examples, without limitation, of excipients include calcium carbonate, calcium phosphate, various sugars and types of starch, cellulose derivatives, gelatin, vegetable oils and polyethylene glycols.

The pharmaceutical composition optionally comprises an additional ingredient which further stabilizes the α-galactosidase of the multimeric protein structure. Optionally, the additional ingredient is galactose.

Alternatively, a galactose derivative (e.g., a galactose-containing glycoside) may be used instead of galactose. Optionally, a non-reducing galactose derivative is used.

Techniques for formulation and administration of drugs may be found in “Remington's Pharmaceutical Sciences” Mack Publishing Co., Easton, PA, latest edition, which is incorporated herein by reference.

Pharmaceutical compositions of the present invention may be manufactured by processes well known in the art, e.g., by means of conventional mixing, dissolving, granulating, dragee-making, levigating, emulsifying, encapsulating, entrapping or lyophilizing processes.

Pharmaceutical compositions for use in accordance with the present invention thus may be formulated in conventional manner using one or more pharmaceutically acceptable carriers comprising excipients and auxiliaries, which facilitate processing of the multimeric protein structure into preparations which can be used pharmaceutically. Proper formulation is dependent upon the route of administration chosen.

For injection or infusion, the multimeric protein structures of embodiments of the invention may be formulated in aqueous solutions, preferably in physiologically compatible buffers such as Hank's solution, Ringer's solution, or physiological saline buffer with or without organic solvents such as propylene glycol, polyethylene glycol.

For transmucosal administration, penetrants are used in the formulation. Such penetrants are generally known in the art.

For oral administration, the multimeric protein structures of the invention can be formulated readily by combining the multimeric protein structures with pharmaceutically acceptable carriers well known in the art. Such carriers enable the multimeric protein structures described herein to be formulated as tablets, pills, dragees, capsules, liquids, gels, syrups, slurries, suspensions, and the like, for oral ingestion by a patient. Pharmacological preparations for oral use can be made using a solid excipient, optionally grinding the resulting mixture, and processing the mixture of granules, after adding suitable auxiliaries if desired, to obtain tablets or dragee cores. Suitable excipients are, in particular, fillers such as sugars, including lactose, sucrose, mannitol, or sorbitol; cellulose preparations such as, for example, maize starch, wheat starch, rice starch, potato starch, gelatin, gum tragacanth, methyl cellulose, hydroxypropylmethyl-cellulose, sodium carbomethylcellulose; and/or physiologically acceptable polymers such as polyvinylpyrrolidone (PVP). If desired, disintegrating agents may be added, such as cross-linked polyvinyl pyrrolidone, agar, or alginic acid or a salt thereof such as sodium alginate.

Dragee cores are provided with suitable coatings. For this purpose, concentrated sugar solutions may be used which may optionally contain gum arabic, talc, polyvinyl pyrrolidone, carbopol gel, polyethylene glycol, titanium dioxide, lacquer solutions and suitable organic solvents or solvent mixtures. Dyestuffs or pigments may be added to the tablets or dragee coatings for identification or to characterize different combinations of doses of active multimeric protein structure.

Pharmaceutical compositions, which can be used orally, include push-fit capsules made of gelatin as well as soft, sealed capsules made of gelatin and a plasticizer, such as glycerol or sorbitol. The push-fit capsules may contain the active ingredients in admixture with filler such as lactose, binders such as starches, lubricants such as talc or magnesium stearate and, optionally, stabilizers. In soft capsules, the multimeric protein structures may be dissolved or suspended in suitable liquids, such as fatty oils, liquid paraffin, or liquid polyethylene glycols. In addition, stabilizers may be added. All formulations for oral administration should be in dosages suitable for the chosen route of administration.

For buccal administration, the compositions may take the form of tablets or lozenges formulated in conventional manner

For administration by inhalation, the multimeric protein structures for use according to embodiments of the present invention are conveniently delivered in the form of an aerosol spray presentation (which typically includes powdered, liquified and/or gaseous carriers) from a pressurized pack or a nebulizer, with the use of a suitable propellant, e.g., dichlorodifluoromethane, trichlorofluoromethane, dichloro-tetrafluoroethane or carbon dioxide. In the case of a pressurized aerosol, the dosage unit may be determined by providing a valve to deliver a metered amount. Capsules and cartridges of, e.g., gelatin for use in an inhaler or insufflator may be formulated containing a powder mix of the multimeric protein structures and a suitable powder base such as, but not limited to, lactose or starch.

The multimeric protein structures described herein may be formulated for parenteral administration, e.g., by bolus injection or continuous infusion. Formulations for injection or infusion may be presented in unit dosage form, e.g., in ampoules or in multidose containers with optionally, an added preservative. The compositions may be suspensions, solutions or emulsions in oily or aqueous vehicles, and may contain formulatory agents such as suspending, stabilizing and/or dispersing agents.

Pharmaceutical compositions for parenteral administration include aqueous solutions of the multimeric protein structure preparation in water-soluble form. Additionally, suspensions of the multimeric protein structures may be prepared as appropriate oily injection suspensions and emulsions (e.g., water-in-oil, oil-in-water or water-in-oil in oil emulsions). Suitable lipophilic solvents or vehicles include fatty oils such as sesame oil, or synthetic fatty acids esters such as ethyl oleate, triglycerides or liposomes. Aqueous injection suspensions may contain substances, which increase the viscosity of the suspension, such as sodium carboxymethyl cellulose, sorbitol or dextran. Optionally, the suspension may also contain suitable stabilizers or agents, which increase the solubility of the multimeric protein structures to allow for the preparation of highly concentrated solutions.

Alternatively, the multimeric protein structures may be in powder form for constitution with a suitable vehicle, e.g., sterile, pyrogen-free water, before use.

The multimeric protein structure of embodiments of the present invention may also be formulated in rectal compositions such as suppositories or retention enemas, using, e.g., conventional suppository bases such as cocoa butter or other glycerides.

The pharmaceutical compositions herein described may also comprise suitable solid of gel phase carriers or excipients. Examples of such carriers or excipients include, but are not limited to, calcium carbonate, calcium phosphate, various sugars, starches, cellulose derivatives, gelatin and polymers such as polyethylene glycols.

Pharmaceutical compositions suitable for use in the context of the present invention include compositions wherein the active ingredients are contained in an amount effective to achieve the intended purpose. More specifically, a therapeutically effective amount means an amount of multimeric protein structures effective to prevent, alleviate or ameliorate symptoms of disease or prolong the survival of the subject being treated.

For any multimeric protein structures used in the methods of the invention, the therapeutically effective amount or dose can be estimated initially from activity assays in animals. For example, a dose can be formulated in animal models to achieve a circulating concentration range that includes the IC₅₀ as determined by activity assays (e.g., the concentration of the test protein structures, which achieves a half-maximal increase in a biological activity of the multimeric protein structure). Such information can be used to more accurately determine useful doses in humans

As is demonstrated in the Examples section that follows, a therapeutically effective amount for the multimeric protein structures of embodiments of the present invention may range between about 1 μg/kg body weight and about 500 mg/kg body weight.

Toxicity and therapeutic efficacy of the multimeric protein structures described herein can be determined by standard pharmaceutical procedures in experimental animals, e.g., by determining the EC₅₀, the IC₅₀ and the LD₅₀ (lethal dose causing death in 50% of the tested animals) for a subject protein structure. The data obtained from these activity assays and animal studies can be used in formulating a range of dosage for use in human

The dosage may vary depending upon the dosage form employed and the route of administration utilized. The exact formulation, route of administration and dosage can be chosen by the individual physician in view of the patient's condition. (See e.g., Fingl et al., 1975, in “The Pharmacological Basis of Therapeutics”, Ch. 1 p. 1).

Dosage amount and interval may be adjusted individually to provide plasma levels of the active moiety which are sufficient to maintain the desired effects, termed the minimal effective concentration (MEC). The MEC will vary for each preparation, but can be estimated from in vitro data; e.g., the concentration necessary to achieve the desired level of activity in vitro. Dosages necessary to achieve the MEC will depend on individual characteristics and route of administration. HPLC assays or bioassays can be used to determine plasma concentrations.

Dosage intervals can also be determined using the MEC value. Preparations should be administered using a regimen, which maintains plasma levels above the MEC for 10-90% of the time, preferable between 30-90% and most preferably 50-90%.

Depending on the severity and responsiveness of the condition to be treated, dosing can also be a single administration of a slow release composition described hereinabove, with course of treatment lasting from several days to several weeks or until cure is effected or diminution of the disease state is achieved.

The amount of a composition to be administered will, of course, be dependent on the subject being treated, the severity of the affliction, the manner of administration, the judgment of the prescribing physician, etc.

Compositions of the present invention may, if desired, be presented in a pack or dispenser device, such as an FDA (the U.S. Food and Drug Administration) approved kit, which may contain one or more unit dosage forms containing the active ingredient. The pack may, for example, comprise metal or plastic foil, such as, but not limited to a blister pack or a pressurized container (for inhalation). The pack or dispenser device may be accompanied by instructions for administration. The pack or dispenser may also be accompanied by a notice associated with the container in a form prescribed by a governmental agency regulating the manufacture, use or sale of pharmaceuticals, which notice is reflective of approval by the agency of the form of the compositions for human or veterinary administration. Such notice, for example, may be of labeling approved by the U.S. Food and Drug Administration for prescription drugs or of an approved product insert. Compositions comprising a multimeric protein structure of embodiments of the invention formulated in a compatible pharmaceutical carrier may also be prepared, placed in an appropriate container, and labeled for treatment of an indicated condition or diagnosis, as is detailed herein.

Thus, according to an embodiment of the present invention, depending on the selected multimeric protein structures, the pharmaceutical composition described herein is packaged in a packaging material and identified in print, in or on the packaging material, for use in the treatment of a condition in which the activity of the multimeric protein structure is beneficial, as described hereinabove.

As used herein the term “about” refers to ±10%

The terms “comprises”, “comprising”, “includes”, “including”, “having” and their conjugates mean “including but not limited to”.

The term “consisting of” means “including and limited to”.

The word “exemplary” is used herein to mean “serving as an example, instance or illustration”. Any embodiment described as “exemplary” is not necessarily to be construed as preferred or advantageous over other embodiments and/or to exclude the incorporation of features from other embodiments.

The word “optionally” is used herein to mean “is provided in some embodiments and not provided in other embodiments”. Any particular embodiment of the invention may include a plurality of “optional” features unless such features conflict.

As used herein, the singular form “a”, “an” and “the” include plural references unless the context clearly dictates otherwise. For example, the term “a compound” or “at least one compound” may include a plurality of compounds, including mixtures thereof.

Throughout this application, various embodiments of this invention may be presented in a range format. It should be understood that the description in range format is merely for convenience and brevity and should not be construed as an inflexible limitation on the scope of the invention. Accordingly, the description of a range should be considered to have specifically disclosed all the possible subranges as well as individual numerical values within that range. For example, description of a range such as from 1 to 6 should be considered to have specifically disclosed subranges such as from 1 to 3, from 1 to 4, from 1 to 5, from 2 to 4, from 2 to 6, from 3 to 6 etc., as well as individual numbers within that range, for example, 1, 2, 3, 4, 5, and 6. This applies regardless of the breadth of the range.

Whenever a numerical range is indicated herein, it is meant to include any cited numeral (fractional or integral) within the indicated range. The phrases “ranging/ranges between” a first indicate number and a second indicate number and “ranging/ranges from” a first indicate number “to” a second indicate number are used herein interchangeably and are meant to include the first and second indicated numbers and all the fractional and integral numerals therebetween.

As used herein the term “method” refers to manners, means, techniques and procedures for accomplishing a given task including, but not limited to, those manners, means, techniques and procedures either known to, or readily developed from known manners, means, techniques and procedures by practitioners of the chemical, pharmacological, biological, biochemical and medical arts.

As used herein, the term “treating” includes abrogating, substantially inhibiting, slowing or reversing the progression of a condition, substantially ameliorating clinical or aesthetical symptoms of a condition or substantially preventing the appearance of clinical or aesthetical symptoms of a condition.

It is appreciated that certain features of the invention, which are, for clarity, described in the context of separate embodiments, may also be provided in combination in a single embodiment. Conversely, various features of the invention, which are, for brevity, described in the context of a single embodiment, may also be provided separately or in any suitable subcombination or as suitable in any other described embodiment of the invention. Certain features described in the context of various embodiments are not to be considered essential features of those embodiments, unless the embodiment is inoperative without those elements.

Various embodiments and aspects of the present invention as delineated hereinabove and as claimed in the claims section below find experimental support in the following examples.

EXAMPLES

Reference is now made to the following examples, which together with the above descriptions illustrate some embodiments of the invention in a non limiting fashion.

Materials and Methods

Materials:

bis-N-hydroxysuccinimide-poly(ethylene glycol) (bis-NHS-PEG) was obtained from Iris Biotech GmbH in PEG₈ and 2000 Dalton (PEG₄₅) PEG forms, and from Pierce in PEG₅ form, and dissolved in dimethyl sulfoxide (DMSO) at a concentration of mg/mL;

Citric acid was obtained from Sigma;

Coomassie Blue G250 was obtained from Bio-Rad;

Dimethyl sulfoxide was obtained from Sigma;

D-(+)-galactose was obtained from Sigma;

Human plasma (K3 EDTA) was obtained from Bioreclamation Inc.;

4-Methylumbelliferone was obtained from Sigma;

4-Methylumbelliferyl-α-D-galactopyranoside was obtained from Sigma;

N-dodecanoyl-nitrobenzoxadiazole-ceramide trihexoside (Gb₃-NBD) was obtained from Matreya;

2-(N-morpholino)ethanesulfonic acid was obtained from Merck;

Phosphate buffered saline was obtained from Sigma;

p-Nitrophenyl-α-D-galactopyranoside was obtained from Sigma;

Primuline was obtained from Sigma; Primuline spray reagent was prepared by dissolving 12.5 mg primuline in 200 ml acetone:water (8:2 volume ratio);

Pyridine was obtained from Sigma;

Sinapinic acid was obtained from Sigma;

Sodium carbonate was obtained from Sigma;

Sodium phosphate was obtained from Sigma;

Sodium taurocholate was obtained from Sigma;

Trifluoroacetic acid was obtained from Sigma. 5

Plant recombinant human α-GAL-I:

Plant recombinant human α-GAL (prh-α-GAL) having SEQ ID NO: 1, referred to herein as plant recombinant human α-GAL-I (prh-α-GAL-I), was prepared as described in International Patent Application PCT/IL2008/000576 (published as WO 2008/132743).

Transgenic plant material was generated using Nicotiana Benthamiana plants infiltrated with genetic construct containing the expression cassette for α-GAL-A, for expressing the human α-GAL-A protein. This was performed in a growth chamber under controlled conditions. This was followed by harvest of plant material and extraction of soluble proteins from the plant cells. prh-α-GAL-A was then purified by a purification process involving standard methods for protein purification followed by a chemical modification step to manufacture the cross-linked protein. The current prh-α-GAL-A was extracted from plant material using homogenizers. The plant debris was removed by centrifugation and the protein was further purified using ammonium sulfate precipitation and acidification steps. The supernatant was filtered and loaded onto a hydrophobic column, followed by desalting and loading onto a cation exchange column. The pool of the cation exchange column was concentrated.

Plant recombinant human α-GAL-II:

Plant recombinant human α-GAL comprising a mixture of α-GAL having SEQ ID NO: 2 and α-GAL having SEQ ID NO: 3 (without the N-terminal amino acids EF present in SEQ ID NO: 1), referred to herein as prh-α-GAL-II, was prepared by a process similar to that described above for prh-α-GAL-I, using a different genetic construct.

cDNA encoding the human α-galactosidase protein (EC 3.2.1-22 GenBank: X05790) was optimized and synthesized by GENEART AG (Regensburg, Germany) The codon usage without the leader peptide (endoplasmic reticulum target signal peptide) was adapted to the codon bias of Nicotiana tobaccum genes. During the optimization process the following cis-acting sequence motifs were avoided: internal TATA-boxes, chi-sites and ribosomal entry sites, AT-rich or GC-rich sequence stretches, RNA instability elements (“killer motifs”), repeat sequences and RNA secondary structures, splice donor (cryptic) and acceptor sites, branch points. In addition, regions of very high (>80%) or very low (<30%) GC content has been avoided.

The nucleotide sequence of the native human α-galactosidase leader peptide (endoplasmic reticulum target signal peptide) of full length human α-galactosidase protein (GenBank: X05790) was replaced with a nucleotide sequence encoding the 33 amino acid endoplasmic reticulum targeting signal peptide (leader peptide) of the Arabidopsis ABPI protein. This signal peptide provides efficient targeting of α-galactosidase to the secretory pathway and is cleaved from the polypeptide, by signal peptidase, once the protein has been translocated into the endoplasmic reticulum. A nucleotide sequence encoding the endoplasmic reticulum retention signal SEKDEL was added to the cDNA sequence at the 3′ terminus, allowing retrieval of the expressed protein from the Golgi apparatus, effectively maintaining the protein in the endoplasmic reticulum.

The protein of interest was expressed from a strong subgenomic viral promoter of the coat protein. The system relies on transient amplification (by agroinfection) of viral vectors delivered to a plant by Agrobacterium. In agroinfection, a plant functional promoter and the cDNA encoding a viral replicon are transferred as T-DNA from Agrobacterium into plant cells. The T-DNA is transcribed in planta by the plant promoter to generate biologically active viral RNA that initiates self replication.

For the transient expression a 3 vector recombination system based on the system previously developed as described [Gleba et al., Vaccine 2005, 23:2042-2048]. One of the vectors was inserted with α-galactosidase cDNA and the two other vectors containing genes for construction of the whole viral replicon (RdRp and Integrase), thus generating the biologically active viral RNA that can initiate self replication

N. Benthamiana plants were germinated and grown in commercial mix soil (Givaat Ada, Ill.) supplemented with granular slow release fertilizer (Scott Marysville, Ohio) under a long day (16 hours light/8 hours dark) light regime at 24-25° C.

Agrobacteria were transformed with the pICH20866-alpha-GAL based replicon vector system using electroporation (2500 V, 5 milliseconds) [den Dulk-Ra and Hooykaas, Methods Mol Biol 1995, 55:63-72]. Plants were infiltrated with Agrobacteria containing the 3 ICON plasmids by vacuum infiltration with standard methods known in the art. Briefly, N. benthamiana plants, 5-6 week old, were infiltrated by immersing all aerial plant organs into a bacterial suspension and were placed in a vacuum chamber. A minus (−) 0.8 bar vacuum was applied for 1 minute, followed by a quick return to atmospheric pressure. Plants were returned to the greenhouse for additional 5-7 days under the same growth conditions.

Samples of Nicotiana benthamiana leaves were harvested 5 days post infiltration and extracted in Laemmli buffer for SDS-PAGE, or in activity assay buffer (20 mM citric acid, 30 mM sodium phosphate, 0.1% bovine serum albumin and 0.67% ethanol, pH 4.6.) for assay of catalytic activity of the plant expressed protein.

Human α-galactosidase protein from plant extracts was purified by a two-step ammonium sulfate differential precipitation (“salting out”: 1^(st) step 0.57 M; 2^(nd) step 2.27 M), followed by hydrophobic interaction chromatography (Phenyl 650 M resin) and cation exchange chromatography.

Two sequences (i.e., SEQ ID NO: 2 and SEQ ID NO: 3), which differ in the presence or absence of an N-terminal glycine, were obtained due to different leader sequence processing.

4-Methylambelliferyl-α-D-galactopyranoside assay of α-GAL activity:

α-GAL activity was measured using 4-methylumbelliferyl-α-D-galactopyranoside as a hydrolysis substrate. The assay was performed in citrate-phosphate buffer (20 mM citric acid, 30 mM sodium phosphate, pH 4.6). 10 μL of sample containing the tested α-GAL was incubated with 40 μL assay buffer containing 5 mM 4-methylumbelliferyl-α-D-galactopyranoside. The reaction mixture was incubated at 37° C. for 60 minutes. 10 μL of the reaction mixture were transferred into a black 96-well plate (Greiner), 90 μL of stop solution (2 M sodium carbonate) was added, and fluorescence was measured at an excitation wavelength of 365 nm and an emission wavelength of 450 nm. Fluorescence was translated to product concentration, and further to activity, using a calibration curve of 4-methylumbelliferone, the reaction product.

N-Dodecanoyl-nitrobenzoxadiazole-ceramide trihexoside (Gb₃-NBD) assay of α-GAL activity

The fluorescently labeled substrate N-dodecanoyl-nitrobenzoxadiazole-ceramide trihexoside (Gb₃-NBD) is less lipophilic than Gb₃, facilitating its use in in-vitro enzymatic reactions.

10 μL of 0.1 μg/μL Gb₃-NBD (in water with 10% ethanol), and 5 μL of 0.2 mg/mL α-GAL were added to 85 μL of citrate-phosphate buffer at a pH of 4.6. The final α-GAL concentration was 10 μg/mL. The background or non-catalyzed reaction, without α-GAL, was composed of 90 μL of citrate-phosphate buffer at a pH of 4.6 with 10 μL of 0.1 μg/μL Gb₃-NBD (in water with 10% ethanol). The reaction mixtures were incubated for 60 minutes at 37° C. Following the incubation, 50 μL methanol was added to the reaction mixture, and the solutions were vortexed for 1 minute. 100 μL chloroform was then added, and the solutions were further vortexed for 1 minute. Water and organic solvents were removed under vacuum using a Speed Vac system. The residues were dissolved in 80 μL of chloroform:methanol (1:1). 30 μL of each sample was loaded on HPTLC (high performance thin layer chromatography) Silica Gel 60 plates (Merck) using a Linomat V system (CAMAG). HPTLC plates were developed using a chloroform:methanol:H₂O solution at a ratio of 100:42:6 as a solvent system. Plates were then allowed to dry and the substrate and product spots were visualized by irradiation under UV light at a wavelength of 365 nm.

p-Nitrophenyl-α-D-galactopyranoside (p-NP-G) assay of α-GAL activity:

p-Nitrophenyl-α-D-galactopyranoside was used as a hydrolysis substrate for α-GAL activity assays. The assay buffer contained 20 mM citric acid, 30 mM sodium phosphate, 0.1% BSA (bovine serum albumin) and 0.67% ethanol at pH 4.6. The assay was performed in 96 well ELISA plates (Greiner). 50 μL of sample were incubated with 150 μL assay buffer and 30 μL substrate was added to obtain a final concentration of 8 mM p-nitrophenyl-α-D-galactopyranoside. The reaction mixture was incubated at 37° C. for 90 minutes. After 90 minutes, 100 μL of 1.98 M sodium carbonate was added to each well in order to terminate the reaction. The amount of reaction product was determined by measuring absorbance at 405 nm.

Measurement of α-GAL stability in vitro:

The stability of α-GAL from various sources was determined by adding α-GAL to one of the following conditions:

1) simulated lysosomal conditions: citrate-phosphate buffer (20 mM citric acid, 30 mM sodium phosphate), pH 4.6, 37° C.;

2) simulated physiological conditions: phosphate buffered saline (PBS), pH 7.4, 37° C.;

3) human plasma at 37° C.

The α-GAL was added at a concentration of 1 μg/mL, as determined by the activity of α-GAL in the solution, and the solution was incubated at 37° C. Samples of each solution were withdrawn at predetermined time points and the α-GAL activity was measured as described hereinabove. The value of the enzymatic activity immediately after addition of the tested α-GAL to each environment was defined as 100%, and further activity results at the tested time points were calculated as a percentage of that initial activity.

Pharmacokinetics of α-GAL:

Individual Fabry (α-Gal-A −/0) mice were placed in an illuminated plexiglass restraining device, and the enzyme was injected into the tail vein. Blood samples were obtained at the indicated times after injection by either tail bleed or retro-orbital eye bleed, using heparinized microhematocrit tubes. Plasma was diluted in 4-methylumbelliferyl-α-D-galactopyranoside activity buffer. A 4-methylumbelliferyl-α-D-galactopyranoside assay was performed as described above.

Terminal elimination half-life (T_(1/2)) was calculated based on plasma activity results. The terminal half-life (elimination half-life) is the time required for the plasma concentration to decrease by 50% after pseudo-equilibrium of distribution has been reached. The terminal half-life was calculated from the terminal (log-linear) portion of the curve, by linear regression of time vs. log concentration [Toutain & Bousquet-Melou, J Vet Pharmacol Ther 2004, 27:427-39].

Bio-Distribution of α-GAL:

Fabry (α-Gal-A −/0) mice were injected intravenously (in the tail vein) with α-GAL at a dose of 2 mg/Kg. Tissues (livers, kidneys, hearts, and spleens) were harvested 2 hours, 24 hours, 3 days, 7 days, 14 days or 28 days post-injection of the enzyme. α-GAL levels in normal control mice and in saline-administered (untreated) Fabry mice were compared with the levels in Fabry mice that received exogenous α-GAL. To determine the α-GAL activity in tissues, thawed tissue samples were placed in 2 mL polypropylene tubes containing lysis buffer (28 mM citric acid, 44 mM dibasic sodium phosphate, 0.5% sodium taurocholate, pH 4.4) as described in Oshima et al. [PNAS 1997, 94:2540-2544]. The samples were homogenized by use of a Tissuelyzer (Retsch MM400) for 10 minutes. Debris was pelleted by centrifugation at 4° C., and the resulting supernatants were assayed for α-GAL activity by a 4-methylumbelliferyl-α-D-galactopyranoside assay, as described above. The same samples were also subjected to Western blot analysis.

In Vivo Gb₃ Assay:

The end point efficacy of injected α-GAL was measured by assay of Gb₃ levels of the animal tissues, in order to determine whether Gb₃ levels were decreased by α-GAL activity.

To measure Gb₃ hydrolysis, neutral glycosphingolipids were extracted from target organs (e.g., liver, kidney, heart and spleen). 100 mg tissue samples were homogenized in 1 mL of 2:1 (v/v) chloroform:methanol and centrifuged for 20 minutes at 13,500 rpm. 62 μL of water was added to 1 mL homogenate to yield a solution of 20:10:2 chloroform:methanol:water. 10 μL pyridine was added to the homogenate to give a final pyridine concentration of 1%. The sample was agitated for 24 hours at 48° C. Solvents and water were removed under vacuum using a SpeedVac system. The sample was resuspended in 2.5 mL methanol and 250 μL of 1 M KOH in methanol was then added. The sample was then shaken for 2 hours at 37° C. The saponification reaction was stopped by the addition of 10 μL of acetic acid. 2.5 mL chloroform was then added to the sample, followed by the addition of 2.5 mL cold water. The sample was vigorously shaken for 5 minutes and was allowed to rest for 5 minutes to allow phase separation. The upper phase, composed of methanol and water, was discarded, and the lower phase, composed of chloroform and methanol, was evaporated under vacuum (SpeedVac), and the residue was resuspended in 300 μL of 1:1 (v/v) chloroform:methanol for analysis of the glycosphingolipids by HPTLC.

Qualitative and semiquantitative analyses of tissue glycolipids were performed by high performance thin layer chromatography (HPTLC) (CAMAG, Switzerland). HPTLC analysis was performed on HPTLC silica gel 60 glass coated plates (Merck). Samples were loaded on the plates using a Linomat 5 system (CAMAG, Switzerland). Plates were developed using chloroform-methanol-water (60:35:4) as the solvent system. Neutral glycosphingolipids were detected with primuline spray reagent. Gb₃ was identified using porcine red blood cell Gb₃ (Matreya) as a standard, and quantified using a calibration curve of N-heptadecanoyl ceramide trihexoside (Matreya), a semi-synthetic standard. Plates were visualized and relevant spots were quantified using a TLC Scanner III (CAMAG, Switzerland) supported by winCATS software (CAMAG, Switzerland).

SDS-PAGE:

SDS-PAGE was carried out under reduced conditions using a Bio-Rad Criterion™ system and in-house casted 12% acrylamide gel. The gel was stained by Coomassie Blue G250 stain.

IEF (isoelectric focusing):

IEF was carried out using an Invitrogen Novex® mini-cell and precasted IEF gels having a pH range of 3-7 (Invitrogen). The gel was stained by Coomassie Blue G250.

Mass spectrometry (MALDI-TOF):

MALDI-TOF was performed using a Bruker Reflex IV MALDI-ToF Mass-spectrometer system (Bruker-Franzen Analytik GmbH, Germany) and a sinapinic acid/trifluoroacetic acid (TFA) (0.1% TFA/acetonitrile (2:1, v/v)) saturated matrix solution.

Example I In Vitro Stability of Recombinant α-GAL

The in vitro stability of recombinant α-GAL was measured in various conditions as described hereinabove in the Materials and Methods Section. Plant recombinant human α-GAL-I, as well as Fabrazyme® and Replagal® commercial recombinant human α-GAL, were tested.

As shown in FIG. 1, all of the tested types of α-GAL exhibited a loss of activity under simulated lysosomal conditions.

In addition, as shown in FIG. 2, all of the tested types of α-GAL exhibited a loss of activity under simulated physiological conditions. As further shown therein, the presence of 100 mg/mL galactose partially protected the activity of plant recombinant α-GAL-I under such conditions.

Similarly, as shown in FIG. 3, all of the tested types of α-GAL exhibited a loss of activity in human plasma at 37° C.

As shown in FIG. 4, the presence of 100 mg/mL galactose partially protected the activity of plant recombinant α-GAL-I under simulated lysosomal conditions.

Size exclusion chromatography (SEC) experiments at lysosomal and neutral pH levels demonstrated changes in the protein structure (data not shown), while SDS-PAGE and Western blot analyses did not exhibit any degradation of the primary amino acid sequence (data not shown).

These results indicate that α-GAL loses activity under lysosomal conditions and physiological conditions due to alteration of the α-GAL protein structure, and that galactose partially prevents this loss of activity.

Example II Cross-Linking of Plant Recombinant Human α-GAL-I with bis-N-hydroxysuccinimide-poly(ethylene glycol) (bis-NHS-PEG) Agents

Plant recombinant human α-GAL-I (prh-α-GAL-I) was cross-linked at 50:1, 100:1 and 200:1 molar ratios with bis-N-hydroxysuccinimide-poly(ethylene glycol) (bis-NHS-PEG) of various molecular weights, namely bis-NHS-PEG_(S), bis-NHS-PEG_(S) or bis-NHS-PEG₄₅ (bis-NHS-PEG with 2,000 Dalton PEG), the structures of which are shown in FIG. 5.

The bis-NHS-PEG may attach to the protein at two sites on a protein (e.g., lysine residues), thereby forming cross-linking, or at one site on a protein. These two forms of attachment are depicted in FIG. 6.

100 μg α-GAL-I in 28.5 μL of 2-(N-morpholino)ethanesulfonic acid (MES) buffer (25 mM, pH 6) was added to 13.5 μL of phosphate buffer (100 mM, pH 8) containing 100 mg/ml galactose.

α-GAL-I was cross-linked with bis-NHS-PEG_(S) at 1:50, 1:100, and 1:200 protein: reagent molar ratios, by adding bis-NHS-PEG₅ in 8 μL DMSO to the α-GAL-I solution (27.4 μg α-GAL-I solution for a 1:50 molar ratio, 54.8 μg α-GAL-I solution for a 1:100 molar ratio, and 109.7 pg α-GAL-I solution for a 1:200 molar ratio).

α-GAL-I was cross-linked with bis-NHS-PEG₄₅ at 1:50, 1:100, and 1:200 protein: reagent molar ratios, by adding bis-NHS-PEG₄₅ in 8 μL DMSO to the α-GAL-I solution (103 pg α-GAL-I solution for a 1:50 molar ratio, 206 pg α-GAL-I solution for a 1:100 molar ratio, and 412 pg α-GAL-I solution for a 1:200 molar ratio) α-GAL-I was crosslinked with bis-NHS-PEG_(S) at 1:50, 1:100, and 1:200 protein: reagent molar ratios, by adding bis-NHS-PEG_(S) in 11.5 μL DMSO to the α-GAL-I solution (37 pg α-GAL-I for a 1:50 molar ratio, 73 μg α-GAL-I solution for a 1:100 molar ratio, and 146 μg α-GAL-I solution for a 1:200 molar ratio).

After adding the bis-NHS-PEG agent to the α-GAL-I, the reactions were pipetted and agitated on an orbital shaker for 2 hours at room temperature.

In all reactions the excess of bis-NHS-PEG cross-linking reagent was removed by dialysis against saline (50KDa cut off).

The yield of dimer increased with increasing protein concentration and DMSO concentration, reaching up to 30%.

The reaction products were analyzed by SDS-PAGE (sodium dodecyl sulfate-polyacrylamide gel electrophoresis), IEF (isoelectric focusing), Western blot, and MALDI-TOF mass spectrometry, as described hereinabove.

As shown in FIG. 7, the standard native prh-α-GAL-I was observed as a monomer (having a molecular weight of 48 KDa) following gel electrophoresis, whereas following reaction of prh-α-GAL-I with bis-NHS-PEG, prh-α-GAL-I appeared primarily in the form of a dimer (with some monomer present), indicating that the two monomers were covalently linked by cross-linking with bis-NHS-PEG.

As is further shown in FIG. 7, a higher proportion of monomeric prh-α-GAL-I was observed with the shorter cross-linkers, bis-NHS-PEG₅ and bis-NHS-PEG₅, than with the longer cross-linker bis-NHS-PEG₄₅. The bis-NHS-PEG₄₅ yielded a high proportion of cross-linked protein. These results indicate that the shorter cross-linkers are less effective at covalently linking monomers.

As is further shown in FIG. 7, for each of the tested cross-linkers, the molecular weight of the monomeric portion of prh-α-GAL-I increased following reaction with the cross-linker. The increase in molecular weight was greater when a higher ratio of cross-linker to protein was used (e.g., 200:1), and when the molecular weight of the cross-linker was greater (e.g., bis-NHS-PEG₄₅). These results indicate that protein monomers which were not dimerized by cross-linking, were covalently attached to the bis-NHS-PEG cross-linker, i.e., the proteins were PEGylated.

The above results indicate that the use of higher molar excess of cross-linker to protein yields higher levels of α-GAL modification, including both cross-linking to form a dimer and PEGylation of the proteins. However, a molar ratio of 100:1 provided a high level of cross-linking, especially in the reactions using the bis-NHS-PEG₄₅ reagent, such that a molar ratio of 200:1 provided only a marginal addition to the cross-linking efficiency.

As shown in FIG. 8, reacting prh-α-GAL-I with bis-NHS-PEG reduced the isoelectric point (pI) of prh-α-GAL-I, thereby confirming that the bis-NHS-PEG is covalently attached to the prh-α-GAL-I. Attachment of bis-NHS-PEG to prh-α-GAL-I converts basic amine groups in lysine residues to neutral amide groups, thereby reducing the pI. The reduction in pI was more pronounced when a greater molar excess (e.g., 200:1) of bis-NHS-PEG was used, confirming the above results obtained with SDS-PAGE.

As is further shown in FIG. 8, the pI is reduced more by bis-NHS-PEG₅ and bis-NHS-PEG₈ than by bis-NHS-PEG₄₅.

This result indicates that bis-NHS-PEG₅ and bis-NHS-PEG₈ are more likely than bis-NHS-PEG₄₅ to result in PEGylation in which only one terminus of the cross-linker is attached to α-GAL. A cross-linker attached to α-GAL at only one terminus is more effective at reducing the pI because such a cross-linker comprises an acidic carboxylic (—CO₂H) group at the non-attached terminus, in addition to converting a lysine amine group to an amide group at the attached terminus.

As shown in FIG. 9, reacting prh-α-GAL-I with bis-NHS-PEG₄₅ cross-linker increased the molecular weight of the prh-α-GAL-I dimer from 97 KDa to 113 KDa, as determined by MALDI-TOF mass spectrometry. The increase in molecular weight indicates an addition of approximately 8 molecules of bis-NHS-PEG₄₅ to the prh-a-GAL-I dimer.

As shown in FIG. 10, reacting prh-α-GAL-I with a bis-NHS-PEG₈ cross-linker increased the molecular weight of the prh-α-GAL-I dimer from 97 KDa to 104 KDa, as determined by MALDI-TOF mass spectrometry. The increase in molecular weight indicates an addition of approximately 10 molecules of bis-NHS-PEG_(S) to the prh-α-GAL-I dimer.

Example III Activity of Cross-Linked Plant Recombinant Human α-GAL-I

In order to determine whether the cross-linked plant recombinant α-GAL-I (prh-α-GAL-I) described in Example II retained enzymatic activity, the cross-linked prh-α-GAL-I was assayed for its enzymatic activity using the 4-methylumbelliferyl-α-D-galactopyranoside assay described hereinabove.

As shown in Table 1 below, prh-α-GAL-I which was reacted with bis-NHS-PEG₅, bis-NHS-PEG₈ or bis-NHS-PEG₄₅ at molar excesses of 50:1, 100:1 and 200:1 bis-NHS-PEG reagent in all cases exhibited a level of enzymatic activity similar to that of native prh-α-GAL-I. As shown therein, both moderate decreases and moderate increases in activity were observed in some cases, which may be a result of formulation effects. These results indicate that the cross-linking did not reduce the activity of prh-α-GAL-I.

TABLE 1 Activity results of cross-linked plant recombinant human α-GAL I Activity Sample Reagent Molar excess mg/mL standard — — 2 1 Bis-NHS-PEG₅  50:1 2.25 2 Bis-NHS-PEG₅ 100:1 1.30 3 Bis-NHS-PEG₅ 200:1 1.24 4 Bis-NHS-PEG₄₅  50:1 2.82 5 Bis-NHS-PEG₄₅ 100:1 2.76 6 Bis-NHS-PEG₄₅ 200:1 3.48 7 Bis-NHS-PEG₈  50:1 2.18 8 Bis-NHS-PEG₈ 100:1 2.43 9 Bis-NHS-PEG₈ 200:1 1.82

The activity of the bis-NHS-PEG₄₅ cross-linked prh-α-GAL-I was further verified using the N-dodecanoyl-NBD-ceramide trihexoside assay described hereinabove, which assays the activity of α-GAL towards its natural substrate, ceramide trihexoside (Gb₃). Replagal® mammalian recombinant human α-GAL was assayed for comparison.

As shown in FIG. 11, following incubation of the cross-linked plant recombinant human α-GAL-I with the fluorescent substrate, almost all substrate was converted to the product, N-dodecanoyl-nitrobenzoxadiazole-lactosyl ceramide, similarly to the reaction catalyzed by the mammalian recombinant α-GAL (Replagal®). This result confirms that the cross-linking did not impair the enzymatic hydrolytic efficiency of the prh-α-GAL-I, using a close analog of the natural substrate.

Example IV In Vitro Stability of Cross-Linked Plant Recombinant Human α-GAL-I

The in vitro stability of the cross-linked plant recombinant human α-GAL-I (prh-α-GAL-I), obtained as described in Example II, was measured in various conditions as described hereinabove in the Materials and Methods Section. The stability of Fabrazyme® and Replagal® commercial recombinant human α-GALs was measured for comparison.

As shown in FIGS. 12A-12C, the stability of plant recombinant human α-GAL-I under simulated lysosomal conditions was enhanced by cross-linking with bis-NHS-PEG₅ (FIG. 12A), bis-NHS-PEG₈ (FIG. 12B) and bis-NHS-PEG₄₅ (FIG. 12C). As further shown therein, the stability of the cross-linked prh-α-GAL-I over the course of one week compared favorably to the stability of the commercial recombinant human α-GAL. After a small decrease in residual activity during the first 24 hours, the cross-linked prh-α-GAL-I maintained activity, even after 10 days. The initial decrease in activity, observed during the first 24 hours, may reflect the portion of plant recombinant human α-GAL-I that did not undergo cross-linking.

As further shown in FIGS. 12A-12C, prh-α-GAL-I cross-linked by bis-NHS-PEG₄₅ exhibited the highest stability under simulated lysosomal conditions.

The stability of plant recombinant human α-GAL-I in human plasma at 37° C. was also enhanced by cross-linking with bis-NHS-PEG₄₅ (data not shown).

These results indicate that cross-linking α-GAL as described herein can increase the efficacy of α-GAL in vivo by increasing the stability of α-GAL in lysosomes, thereby allowing α-GAL to act for a longer period of time in the lysosomes, and by increasing the stability of α-GAL in the blood, thereby increasing the circulatory half-life of α-GAL.

Example V In Vivo Pharmacokinetics and Bio-Distribution of Cross-Linked Plant Recombinant Human α-GAL-I

The pharmacokinetics and bio-distribution of plant recombinant human α-GAL-I (prh-α-GAL-I) cross-linked with bis-NHS-PEG₄₅ or bis-NHS-PEG₈ as described in Example II was determined in Fabry mice injected with 2 mg/Kg of α-GAL, as described hereinabove in the Materials and Methods Section. The pharmacokinetics and bio-distribution of non-cross-linked plant recombinant human α-GAL-I and of Replagal® recombinant human α-GAL was determined for comparison. Blood samples were collected for pharmacokinetic analysis 1, 3, 5, 10, 20, 30, 40, 60 and 120 minutes post-injection. For each type of α-GAL, the treatment group consisted of six mice.

As shown in Table 2 below, cross-linking prh-α-GAL-I with bis-NHS-PEG₈ and with bis-NHS-PEG₄₅ increased the circulatory terminal half-life of plant recombinant human α-GAL-I, with the latter exhibiting a more pronounced effect.

TABLE 2 Circulatory terminal half-lives of recombinant α-GAL α-GAL sample t_(1/2) (minutes) Replagal ® mammalian recombinant human α-GAL 8.1 Plant recombinant human α-GAL-I 4.8 Plant recombinant human α-GAL I cross-linked with 6.2 bis-NHS-PEG₈ Plant recombinant human α-GAL-I cross-linked with 90 bis-NHS-PEG₄₅

As shown in FIG. 13 and in Table 2, the terminal half-life of prh α-GAL-I cross-linked by bis-NHS-PEG₄₅ was considerably greater than the terminal half-life of Replagal® α-GAL.

As further shown in FIG. 13, the activity of plant recombinant human α-GAL-I cross-linked with bis-NHS-PEG₄₅ at 20 minutes was about 40% of the activity at 1 minute. Furthermore, the cross-linked prh-α-GAL-I exhibited an active plasma presence even 4 hours post-injection.

These results indicate that the cross-linked prh-α-GAL-I remains active in vivo for a relative long time, which can allow the enzyme to reach additional tissues and organs.

As shown in FIGS. 14A and 14B, the levels of plant recombinant α-GAL-I cross-linked with bis-NHS-PEG₈ and bis-NHS-PEG₄₅ in the spleens of Fabry mice 2 hours post-injection were considerably higher than those of non-cross-linked plant recombinant α-GAL-I as well those of Replagal® mammalian recombinant α-GAL. As further shown therein, levels of prh-α-GAL-I cross-linked with bis-NHS-PEG₄₅ were higher than levels of prh-α-GAL-I cross-linked with bis-NHS-PEG₈. The Western blot analyses (FIG. 14B) are consistent with the bio-distribution results obtained by assaying α-GAL enzymatic activity (FIG. 14A).

As shown in FIG. 15A and 15B, the levels of plant recombinant α-GAL-I cross-linked with bis-NHS-PEG₈ and bis-NHS-PEG₄₅ in the livers of Fabry mice 2 hours post-injection were considerably higher than those of non-cross-linked plant recombinant α-GAL-I, but lower than levels of Replagal® mammalian recombinant α-GAL in the liver. As further shown therein, levels of prh-α-GAL-I cross-linked with bis-NHS-PEG₄₅ were slightly higher than levels of prh-α-GAL-I cross-linked with bis-NHS-PEG₈. The Western blot analyses (FIG. 15B) are consistent with the bio-distribution results obtained by assaying α-GAL enzymatic activity (FIG. 15A).

Lower levels of α-GAL in the liver may be therapeutically advantageous, as about 95% of the recovered enzyme in enzyme replacement therapy is typically found in the liver, and hence high levels of recombinant α-GAL in the liver indicate lower levels of exogenous α-GAL in target organs, such as heart and kidneys.

As shown in FIG. 16, the levels of plant recombinant α-GAL-I cross-linked with bis-NHS-PEG₈ and bis-NHS-PEG₄₅ in the hearts of Fabry mice 2 hours post-injection were higher than those of non-cross-linked plant recombinant α-GAL-I. As further shown therein, levels of prh-α-GAL-I cross-linked with bis-NHS-PEG₄₅ were higher than levels of prh-α-GAL-I cross-linked with bis-NHS-PEG₈, as well as levels of Replagal® mammalian recombinant α-GAL.

As shown in FIG. 17, the levels of plant recombinant α-GAL-I cross-linked with bis-NHS-PEG₈ and bis-NHS-PEG₄₅ in the kidneys of Fabry mice 2 hours post-injection were higher than those of non-cross-linked plant recombinant α-GAL-I. As further shown therein, levels of prh-α-GAL-I cross-linked with bis-NHS-PEG₄₅ were higher than levels of prh-α-GAL-I cross-linked with bis-NHS-PEG₈, as well as levels of Replagal® mammalian recombinant α-GAL.

Similarly, as shown in FIGS. 18-21, the levels of plant recombinant α-GAL-I cross-linked with bis-NHS-PEG₄₅ were higher than the levels of non-cross-linked plant recombinant α-GAL-I in the spleen (FIG. 18), liver (FIG. 19), heart (FIG. 20) and kidneys (FIG. 21) of Fabry mice, for up to 7 days post-injection. As further shown therein, the levels of plant recombinant α-GAL-I cross-linked with bis-NHS-PEG₄₅ were higher than the levels of Replagal® mammalian recombinant α-GAL in the spleen, heart and kidneys.

These results indicate that α-GAL cross-linked with bis-NHS-PEG, particularly bis-NHS-PEG₄₅, exhibits enhanced uptake into organs, including the kidney and heart, which are major target organs in the treatment of Fabry disorder. These results are consistent with the increased circulatory half-life and enhanced stability of cross-linked α-GAL.

Example VI Cross-Linking of Mammalian Recombinant Human α-GAL with bis-N-hydroxysaccinimide-poly(ethylene glycol) (bis-NHS-PEG)

In order to confirm the advantageous effects of cross-linking described hereinabove, Replagal® mammalian recombinant human α-GAL, which is produced from human fibrosarcoma line HT-1080, was cross-linked.

333 μL of phosphate buffer (100 mM, pH 8) with 100 mg/ml D-(+)-galactose was added to 3.8 mg bis-NHS-PEG₄₅ in 151 μL of DMSO solution (25 mg/mi) and 1.8 mg of Replagal® recombinant human α-GAL in 130 μL citrate buffer (25 mM, pH 6). Replagal® α-GAL concentration was determined by an activity assay. The reaction mixture was agitated using an orbital shaker for 2 hours at room temperature. The excess of bis-NHS-PEG₄₅ cross-linking reagent was removed by dialysis against saline using a Vivaspin 6 concentrator with a cut-off of 50 KDa. The α-GAL activity of the cross-linked Replagal® α-GAL indicated that the α-GAL concentration was 3 mg/mL.

The reaction products were analyzed by SDS-PAGE (sodium dodecyl sulfate-polyacrylamide gel electrophoresis), IEF (isoelectric focusing), and MALDI-TOF mass spectrometry, as described hereinabove.

As shown in FIG. 22, the standard native Replagal® α-GAL was observed as a monomer following gel electrophoresis, whereas following reaction of Replagal® α-GAL with bis-NHS-PEG₄₅, the α-GAL appeared in the form of a dimer, indicating that the two monomers were covalently linked by cross-linking with bis-NHS-PEG.

As shown in FIG. 23, reacting Replagal® α-GAL with bis-NHS-PEG₄₅ reduced the isoelectric point (pI) of the α-GAL, thereby confirming that the bis-NHS-PEG is covalently attached to the α-GAL.

As shown in FIG. 24, reacting Replagal® α-GAL with bis-NHS-PEG₄₅ cross-linker increased the molecular weight of the Replagal® α-GAL dimer from 103.0 KDa to 121.3 KDa, as determined by MALDI-TOF mass spectrometry. The increase in molecular weight indicates an addition of approximately 9-10 molecules of bis-NHS-PEG₄₅ to the α-GAL dimer, which is similar to results described hereinabove for prh-α_(GAL)-_(I).

Example VII Activity of Cross-Linked Mammalian Recombinant Human α-GAL

In order to determine whether the cross-linking of mammalian recombinant α-GAL described in Example VI affected enzymatic activity, the cross-linked α-GAL was assayed for its enzymatic activity using a p-nitrophenyl-α-D-galactopyranoside (pNP-G) assay, according to the procedures described hereinabove.

As shown in FIG. 25 and in Table 3 below, mammalian recombinant human α-GAL which was cross-linked with bis-NHS-PEG₄₅ exhibited parameters of enzymatic activity which are very similar to those of native mammalian recombinant human α-GAL. These results indicate that the cross-linking did not significantly affect the activity or the catalytic machinery and mechanism of the mammalian recombinant human α-GAL.

TABLE 3 Activity results of cross-linked mammalian recombinant human α-GAL K_(M) V_(max) k_(cat) k_(cat)/K_(M) Sample (μM) (μM/minute) (second⁻¹) (second⁻¹*μM⁻¹) Replagal ® 3212 ± 98  4.20 ± 0.05 67.2 ± 1 0.0209 ± 0.001 α-GAL Cross-linked 3419 ± 162 4.43 ± 0.07 70.9 ± 1 0.0210 ± 0.001 Replagal ® α-GAL

Example VIII In vitro stability of Cross-Linked Mammalian Recombinant Human α-GAL

The in vitro stability of the cross-linked Replagal® mammalian recombinant human α-GAL, obtained as described in Example VI, was measured in various conditions as described hereinabove in the Materials and Methods Section. The stability of non-cross-linked Replagal® α-GAL was measured for comparison, in order to assess the effect of cross-linking.

As shown in FIGS. 26A and 26B, the stability of mammalian recombinant human α-GAL under both simulated lysosomal conditions (FIG. 26A) and in human plasma (FIG. 26B) was considerably enhanced by cross-linking with bis-NHS-PEG₄₅. The cross-linked mammalian recombinant human α-GAL exhibited higher stability under simulated lysosomal conditions than in plasma.

These results indicate that the cross-linking of α-GAL as described herein can stabilize recombinant α-GAL from multiple sources and expression platforms.

Example IX In Vivo Pharmacokinetics and Bio-Distribution of Cross-Linked Mammalian Recombinant Human α-GAL

The pharmacokinetics and bio-distribution of the cross-linked mammalian recombinant human α-GAL described in Example VI was determined by measuring α-GAL activity in the spleen, liver, heart and kidneys of Fabry mice 2 hours, 7, 14, and 28 days post-injection, as well as Gb₃ levels in these organs, as described hereinabove in the Materials and Methods section. The bio-distribution of non-cross-linked Replagal® mammalian recombinant human α-GAL was determined for comparison.

As shown in FIGS. 27A-27D, the levels of cross-linked mammalian recombinant α-GAL in the spleens (FIG. 27A), liver (FIG. 27B), heart (FIG. 27C) and kidneys (FIG. 27D) of Fabry mice were considerably higher than those of non-cross-linked mammalian recombinant α-GAL.

As shown in FIGS. 28A-28D, cross-linked mammalian recombinant α-GAL decreased Gb₃ levels in the heart (FIG. 28A), kidney (FIG. 28B), liver (FIG. 28C) and spleen (FIG. 28D) of Fabry mice, over the course of 28 days post-injection. Cross-linked mammalian recombinant α-GAL decreased Gb₃ levels to a greater extent than did non-cross-linked recombinant α-GAL in the kidney (FIG. 28B) and spleen (FIG. 28D) of Fabry mice, and to about the same extent as non-cross-linked mammalian recombinant α-GAL in the heart (FIG. 28A) and liver (FIG. 28C).

These results indicate that cross-linking with bis-NHS-PEG results in considerably enhanced uptake of recombinant α-GAL from a variety of sources and expression platforms into organs, including the kidney and heart, which are major target organs in the treatment of Fabry disorder. These results further indicate that cross-linking with bis-NHS-PEG results in a more substantial decrease of Gb₃ levels in organs.

Example X Cross-Linking of Plant Recombinant Human α-GAL-H with bis-N-hydroxysuccinimide-poly(ethylene glycol) (bis-NHS-PEG)

Plant recombinant human α-GAL-II (prh-α-GAL-II), which lacks the amino acids EF present in the N-terminus of prh-α-GAL-I, was cross-linked with bis-NHS-PEG₄₅, bis-NHS-PEG₂₁, or bis-NHS-PEG₆₈ at a 200:1 molar ratio of bis-NHS-PEG to α-GAL, according to the protocol described in Example II.

The prh-α-GAL-II retained its biological activity following cross-linking with bis-NHS-PEG (data not shown).

The reaction products were analyzed by SDS-PAGE (sodium dodecyl sulfate-polyacrylamide gel electrophoresis) and MALDI-TOF mass spectrometry, as described hereinabove.

As shown in FIGS. 29A-29B, the standard native prh-α-GAL-II was observed as a monomer following gel electrophoresis, whereas following reaction of prh-α-GAL-II with bis-NHS-PEG₄₅ or bis-NHS-PEG₂₁ (FIG. 29A), or with bis-NHS-PEG₆₈ (FIG. 29B), prh-α-GAL-II appeared primarily in the form of a dimer (with some monomer present), indicating that the two monomers were covalently linked by cross-linking with a bis-NHS-PEG cross-linking agent.

As is further shown in FIGS. 29A-29B, for each of the tested cross-linkers, the molecular weight of the monomeric portion of prh-α-GAL-II increased following reaction with the cross-linker. The increase in molecular weight was greater for bis-NHS-PEG₄₅ than for bis-NHS-PEG₂₁ (FIG. 29A), and was greatest for bis-NHS-PEG₆₈ (compare FIG. 29A with FIG. 29B). These results indicate that the monomers which were not dimerized by cross-linking, were covalently attached to the bis-NHS-PEG cross-linker, i.e., the proteins were PEGylated.

As shown in FIGS. 30A-30C, reacting prh-α-GAL-II with bis-NHS-PEG₂₁ cross-linker increased the molecular weight of the prh-α-GAL-II dimer from 95 KDa (FIG. 30A) to 109 KDa (FIG. 30B), while reacting prh-α-GAL-II with bis-NHS-PEG₄₅ cross-linker increased the molecular weight of the prh-α-GAL-II dimer to 114 KDa (FIG. 30C), as determined by MALDI-TOF mass spectrometry. The increase in molecular weight indicates an addition of approximately 13 molecules of bis-NHS-PEG₂₁, or approximately 9 molecules of bis-NHS-PEG₄₅, to the prh-α-GAL-II dimer.

Example XI In Vitro Stability of Cross-Linked Plant Recombinant Human α-GAL-II

The in vitro stability of the cross-linked plant recombinant human α-GAL-II (prh-α-GAL-II) obtained as described in Example X was measured under various conditions as described hereinabove in the Materials and Methods Section. The stability of Replagal® commercial recombinant human α-GAL was measured for comparison.

As shown in FIGS. 31A-31D, the stability of plant recombinant human α-GAL-II was enhanced by cross-linking with either bis-NHS-PEG₆₈ (FIGS. 31B and 31D), bis-NHS-PEG₄₅ (FIGS. 31A-31D) or bis-NHS-PEG₂₁ (FIGS. 31A and 31C), under both simulated lysosomal conditions (FIGS. 31A and 31B) and in human plasma (FIGS. 31C and 31D). The different cross-linkers enhanced the stability of prh-α-GAL-II to comparable extents. As further shown therein, the stability of the cross-linked prh-α-GAL-II was greater than the stability of the Replagal® recombinant human α-GAL. The cross-linked prh-α-GAL-II exhibited higher stability under simulated lysosomal conditions as well as under plasma conditions.

As further shown in FIGS. 31A-31D, non-cross-linked prh-α-GAL-II is considerably more stable than non-cross-linked prh-α-GAL-I (see FIGS. 1 and 3 for comparison), under both simulated lysosomal conditions (FIGS. 1 and 31A-31B) and in human plasma (FIGS. 3 and 31C-31D), although prh-α-GAL-II still exhibits some instability.

These results indicate that the cross-linking of α-GAL as described herein can stabilize different types of α-GALs.

Example XII In Vivo Pharmacokinetics and Bio-Distribution of Cross-Linked Plant Recombinant Human α-GAL-II

The pharmacokinetics and bio-distribution of the PEG₄₅-cross-linked and PEG₂₁-cross-linked plant recombinant human α-GAL-II (prh-α-GAL-II), described in Example X, was determined by measuring α-GAL activity in plasma and organs as described hereinabove in the Materials and Methods section. The pharmacokinetics and bio-distribution of non-cross-linked Replagal® mammalian recombinant human α-GAL were determined for comparison.

Blood samples were collected for pharmacokinetic analyses at 1, 5, 10, 30, 60, 120, 240, 480 and 1440 minutes after injection of Fabry mice with 1 mg/Kg of α-GAL.

Bio-distribution of α-GAL was determined by harvesting the liver, kidneys, heart and spleen of Fabry mice 2 hours, 7 days, 14 days and 28 days post-injection with 2 mg/Kg α-GAL.

As shown in FIGS. 32A and 32B and in Table 4, cross-linking of prh-α-GAL-II with bis-NHS-PEG₄₅ considerably increased the circulatory terminal half-life of prh-α-GAL-II, yielding a circulatory half-life considerably greater than that of mammalian recombinant α-GAL or of non-cross-linked prh-α-GAL-II.

TABLE 4 Circulatory terminal half-life of recombinant α-GAL Test item t_(1/2) (min) Replagal ® α-GAL 13.3 plant recombinant alpha-GAL-II 4.8 plant recombinant alpha-GAL-II cross- 581.6 linked with bis-NHS-PEG₄₅

As shown in FIGS. 33A-33L, cross-linking of prh-α-GAL-II with bis-NHS-PEG₄₅ increased the uptake of prh-α-GAL-II in heart (FIG. 33A), kidney (FIG. 33B), liver (FIG. 33C) and spleen (FIG. 33D) of Fabry mice, although to a lesser degree in the liver.

As shown in FIGS. 33E-33L, cross-linking of prh-α-GAL-II with bis-NHS-PEG₂₁ also increased the uptake of prh-α-GAL-II in heart (FIGS. 33E and 33I), kidney (FIGS. 33F and 33J), liver (FIGS. 33G and 33K) and spleen (FIGS. 33H and 33L) of Fabry mice, although such an increase was not always evident after only 2 hours.

As further shown therein, the levels of cross-linked prh-α-GAL-II were greater than the levels of mammalian recombinant α-GAL in the heart (FIGS. 33A, 33E and 33I), kidney (FIGS. 33B, 33F and 33J), and spleen (FIGS. 33D, 33H and 33L) of Fabry mice, and lower than the levels of mammalian recombinant α-GAL in the liver (FIGS. 33C, 33G and 33K).

These results indicate that cross-linked prh-α-GAL-II exhibits considerably enhanced activity of α-GAL in the plasma and in various organs, particularly in organs other than the liver.

Example XIII Effect of pH on Activity of Plant Recombinant Human α-GAL

The pH of the environment has a significant effect on the stability and kinetics of lysosomal enzymes such α-GAL. The pH may affect binding of substrate to the enzyme. The pH can also affect the protonation or deprotonation of catalytic groups, such as carboxyl or amino groups, which are part of the enzyme's active site, and thus affect the kinetic behavior of the enzyme. The stability of the tertiary or quaternary structure of enzymes is also pH-dependent, and affects the velocity of the enzymatic reaction, especially at extremely acidic or alkaline pH values.

The activity of PEG₄₅-cross-linked and non-cross-linked plant recombinant human α-GAL-II was determined at various pH values using a pNP-G substrate, in order to examine the pH-dependence of α-GAL activity, and the effect of cross-linking thereon. The measurements were performed in solutions of 20 mM citrate and 30 mM sodium phosphate.

The kinetic parameters characterizing α-GAL activity at various pH values are summarized in Table 5 below, and in FIGS. 34A-34C.

As shown in FIGS. 34A-34C, cross-linking of the α-GAL-II increased the V_(max) (FIG. 34A) and k_(cat) (FIG. 34C) parameters, and did not have a significant effect on the K_(M) parameter (FIG. 34B).

TABLE 5 Activity results of non-cross-linked plant recombinant human α-GAL-II (prh-α-GAL-II) and PEG₄₅-cross-linked plant recombinant human α-GAL II (prh-α-GAL-II-CL45) at various pH values K_(M) V_(max) k_(cat) k_(cat)/K_(M) pH Sample (μM) (μM/minute) (second⁻¹) (second⁻¹* μM⁻¹) 2.8 prh-α-GAL-II 15216 0.57 9.04 0.0006 prh-α-GAL-II-CL45 13618 0.90 14.37 0.0011 3.2 prh-α-GAL-II 11476 0.55 8.85 0.0008 prh-α-GAL-II-CL45 8489 1.34 21.44 0.0025 3.6 prh-α-GAL-II 11147 1.76 28.16 0.0025 prh-α-GAL-II-CL45 4699 2.23 35.68 0.0076 4.04 prh-α-GAL-II 5709 1.98 31.68 0.0055 prh-α-GAL-II-CL45 3207 2.74 43.76 0.0136 4.4 prh-α-GAL-II 4596 2.40 38.40 0.0084 prh-α-GAL-II-CL45 3122 3.22 51.57 0.0165 4.8 prh-α-GAL-II 4531 2.32 37.12 0.0082 prh-α-GAL-II-CL45 3345 2.95 47.23 0.0141 5.29 prh-α-GAL-II 6793 2.06 32.99 0.0049 prh-α-GAL-II-CL45 3973 2.78 44.48 0.0112 5.66 prh-α-GAL-II 10396 1.75 28.05 0.0027 prh-α-GAL-II-CL45 4883 2.70 43.20 0.0088 6.09 prh-α-GAL-II 11357 1.44 23.04 0.0020 prh-α-GAL-II-CL45 8336 1.54 24.59 0.0030 6.4 prh-α-GAL-II 21046 1.32 21.12 0.0010 prh-α-GAL-II-CL45 16844 1.46 23.36 0.0014 6.76 prh-α-GAL-II 25188 1.12 17.92 0.0007 prh-α-GAL-II-CL45 18313 1.14 18.24 0.0010 7.36 prh-α-GAL-II — — — — prh-α-GAL-II-CL45 32692 0.52 8.37 0.0003

The enhancement of the V_(max) and k_(cat) parameters indicates an increase in catalytic activity. This increase is particularly significant at pH values of at least about 7, where the catalytic activity of non-cross-linked α-GAL-II is negligible.

K_(M) is a kinetic parameter associated with enzyme/substrate affinity. The absence of a significant effect of cross-linking on K_(M) values indicates that the cross-linking has no significant effect on α-GAL affinity to the pNP-G substrate.

Example XIV Effect of PEGylation on Stability of α-GAL

The effect of PEGylation per se on α-GAL stability was ascertained, in order to determine whether the stabilizing effect of PEG cross-linkers is due to the properties of PEG or due to the cross-linking.

Plant recombinant human α-GAL-I was reacted with N-hydroxysuccinimide (NHS)-activated methoxy-capped PEGs with different molecular weights (2, 5, and 10 KDa). Such PEG reagents have a single NHS group, and consequently PEGylate the protein without forming cross-linking. The reaction products were analyzed by SDS-PAGE.

As shown in FIG. 35, the methoxy-capped PEGylating agents PEGylated the α-GAL (visible as an increase in molecular weight of the α-GAL), but did not substantially generate α-GAL dimers, indicating that the α-GAL was not cross-linked.

As shown in FIGS. 36A and 36B, PEGylating plant recombinant human α-GAL-I without forming cross-linking did not substantially increase the stability of the plant recombinant α-GAL, under either simulated lysosomal conditions (FIG. 36A) or in human plasma (FIG. 36B).

These results indicate that the stabilizing effect of the cross-linking described hereinabove is not a result of PEGylation per se.

Example XV Effect of PEG Chain Length on Activity of Cross-Linked α-GAL

In order to assess the effect of the chain length of PEG cross-linkers on α-GAL activity, plant recombinant human α-GAL-I was cross-linked with bis-NHS-PEG₂, bis-NHS-PEG₄, bis-NHS-PEG₆₈ and bis-NHS-PEG₁₅₀ agents, using essentially the same procedures as described in Example II (PEG₆₈ and PEG₁₅₀ are approximate chain lengths). The α-GAL-I was cross-linked at 50:1, 100:1 and 200:1 bis-NHS-PEG:α-GAL molar ratios. The reaction products were analyzed by SDS-PAGE, as described hereinabove. α-GAL-I cross-linked with bis-NHS-PEG₄₅ as described in Example II was also analyzed for comparison.

As shown in FIG. 37, SDS-PAGE analysis showed that all of the bis-NHS-PEG agents cross-linked the α-GAL so as to result in a covalently cross-linked dimer, and that cross-linking was more efficient when a 200:1 molar ratio was used.

The enzymatic activity of the cross-linked α-GAL-I was then determined as described in Example III. The results are summarized in Table 6 below.

TABLE 6 Activity results of cross-linked plant recombinant human α-GAL-I Expected Measured α-GAL α-GAL Molar ratio activity activity Reagent (reagent:α-GAL-I) [mg/mL] [mg/mL] bis-NHS-PEG₂  50:1 2 1.159 100:1 2 1.001

200:1 2 0.970 bis-NHS-PEG₄ 50:1 2 1.399 100:1 2 1.333 200:1 2 1.048 bis-NHS-PEG₆₈  50:1 2 1.822 100:1 2 2.252 200:1 2 2.425 bis-NHS-PEG₁₅₀  50:1 2 1.804 100:1 2 2.031 200:1 2 1.825

As shown in Table 6, cross-linking with PEG₂ and PEG₄ moderately reduced α-GAL activity (by approximately 30-50%), whereas cross-linking with longer PEG chains did not significantly affect α-GAL activity.

These results indicate that cross-linking with PEG chains longer than PEG₄ is advantageous in terms of preserving activity of the cross-linked α-GAL.

Example XVI Cross-Linking of α-GAL using bis-COOH-PEG Agents

As an alternative to the above-described cross-linking of α-GAL using pre-prepared (e.g., commercially available) bis-NHS-PEG agents, α-GAL was cross-linked with bis-COOH-PEG agents by activating the carboxyl (i.e., COOH) groups in situ shortly before the cross-linking reaction was effected.

Bis-COOH-PEG₁₂, bis-COOH-PEG₂₈ and bis-COOH-PEG₄₅ were each activated by being reacted with 1.1 molar equivalents per carboxyl group (i.e., 2.2 molar equivalents per bis-COOH-PEG) of both NHS (N-hydroxysuccinimide) and EDC (1-ethyl-3-(3-dimethylaminopropyl) carbodiimide). The reaction mixture was then shaken in DMSO for 30 minutes at room temperature. The activated bis-COOH-PEG, which is essentially bis-NHS-PEG, was then reacted with plant recombinant human α-GAL-I at molar ratios of 50:1, 100:1 and 200:1, as described in Example II. The reaction products were analyzed by SDS-PAGE, as described hereinabove. α-GAL-I cross-linked with bis-NHS-PEG₄₅ as described in Example II was also analyzed for comparison.

As shown in FIG. 38, SDS-PAGE analysis showed that all of the bis-COOH-PEG agents cross-linked the α-GAL to some extent, but that cross-linking was more efficient when a 200:1 molar ratio was used.

The enzymatic activity of the cross-linked α-GAL-I was then determined as described in Example III. The results are summarized in Table 7 below.

TABLE 7 Activity results of cross-linked plant recombinant human α-GAL-I Expected Measured α-GAL α-GAL Molar ratio activity activity Reagent (reagent:α-GAL-I) [mg/mL] [mg/mL] Bis-HOOC-PEG₁₂  50:1 1.5 1.236 100:1 1.5 1.304 200:1 1.5 1.404 Bis-HOOC-PEG₂₈  50:1 1.5 1.326 100:1 1.5 1.371 200:1 1.5 1.460 Bis-HOOC-PEG₄₅  50:1 1.5 1.349 100:1 1.5 1.541 200:1 1.5 1.628

As shown in Table 7, cross-linking with each of the tested bis-COOH-PEG agents resulted in α-GAL with about the expected activity.

These results indicate that cross-linking bis-COOH-PEG agents does not reduce α-GAL activity in comparison to cross-linking with bis-NHS-PEG agents.

These results further confirm the above-described findings that cross-linking with PEG chains longer than PEG₄ does not significantly reduce the activity of the cross-linked α-GAL.

Example XVII Effect of Length and Type of Cross-Linking Agent on In Vitro Stability of Cross-Linked Plant Recombinant Human α-GAL-I

In order to further characterize the effect of chain length on cross-linked α-GAL stability, and to compare the stability of α-GAL cross-linked with bis-COOH-PEG agents (e.g., as described in Example XVI) with that of α-GAL cross-linked with bis-NHS-PEG agents, the in vitro stability of plant recombinant human α-GAL-I (prh-α-GAL-I) cross-linked with bis-NHS-PEG₂, bis-NHS-PEG₄, bis-COOH-PEG₁₂, bis-COOH₂₈, and bis-COOH-PEG₄₅, obtained as described in Examples XV and XVI, was measured in various conditions as described hereinabove in the Materials and Methods Section, and compared with the stability of prh-α-GAL-I cross-linked with bis-NHS-PEG₄₅ as described in Example II. The stability of Replagal® commercial recombinant human α-GAL and non-crosslinked prh-GAL-I was measured for comparison.

As shown in FIG. 39, the stability of plant recombinant human α-GAL-I under simulated lysosomal conditions was enhanced by cross-linking with each of the bis-NHS-PEG and bis-COOH-PEG agents.

As further shown therein, the stability of the cross-linked prh-α-GAL-I was correlated with the length of the cross-linking PEG chain, with bis-NHS-PEG₄₅ and bis-COOH-PEG₄₅ providing the most stability, and bis-NHS-PEG₂ providing the least stability. However, cross-linking with bis-COOH-PEG₄₅ provided only marginally more stability than did cross-linking with bis-COOH-PEG₄₅, suggesting that above a certain length, the stability is not affected by PEG chain length.

As further shown in FIG. 39, cross-linking with bis-NHS-PEG₄₅ provided slightly more stability than did cross-linking with bis-COOH-PEG₄₅. This may be a result of incomplete activation of the bis-COOH-PEG agent. However the difference in stability was slight.

In addition, cross-linking with each of the bis-NHS-PEG and bis-COOH-PEG agents enhanced the stability of the plant recombinant human α-GAL-I in human plasma at 37° C. (data not shown).

These results provide further evidence that cross-linking α-GAL as described herein can increase the efficacy of α-GAL in vivo by increasing the stability of α-GAL in lysosomes and in the blood, and that PEG chains of about 28-45 units in length are more effective at stabilizing α-GAL by cross-linking than are shorter PEG chains.

Example XVIII Kinetic Parameters of Cross-Linked Plant Recombinant Human α-GAL-II

The kinetic parameters of cross-linked plant recombinant human α-GAL-II, obtained as described in Example X, as well as of non-cross-linked plant recombinant human α-GAL-II, were determined using a pNP-G substrate and Michaelis-Menten analysis, in order to examine the effect of cross-linking thereon. The measurements were performed in a solution of 20 mM citrate, 30 mM sodium phosphate, 0.1% bovine serum albumin and 0.67% ethanol, at a pH of 4.6. The kinetic parameters were calculated using protein content values based on an activity assay.

As shown in Table 8 below, cross-linking of α-GAL-II resulted in improved kinetic properties, as compared with non-cross-linked α-GAL-II. The Michaelis constant (K_(M)) was reduced, indicating higher affinity of the enzyme to the substrate. Furthermore, the k_(cat)/K_(M), which signifies the overall catalytic efficiency of the enzyme with this substrate under the described conditions, was enhanced for the cross-linked species.

TABLE 8 Michaelis-Menten parameters of non-cross-linked plant recombinant human α-GAL-II (prh-α-GAL-II) and plant recombinant human α-GAL II cross-linked with bis-NHS-PEG₂₁ (prh-α-GAL-II-CL21), bis-NHS-PEG₄₅ (prh-α-GAL-II-CL45) or bis-NHS-PEG₆₈ (prh-α-GAL-II-CL68) K_(m) V_(max) k_(cat) k_(cat)/K_(m) Sample (μM) (μM/min) (sec⁻¹) (sec⁻¹ μM⁻¹) prh-α-GAL-II 4801 4.59 73.49 0.015 prh-α-GAL-II-CL21 2661 4.85 77.55 0.029 prh-α-GAL-II-CL45 2583 4.87 77.87 0.030 prh-α-GAL-II-CL68 2556 4.12 65.97 0.026

Example XIX Reproducibility of Cross-Linking of Plant Recombinant Human α-GAL-II

The batch-to-batch reproducibility of cross-linking was assessed after preparing 5 batches of plant recombinant human α-GAL-II (prh-α-GAL-II) cross-linked with bis-NHS-PEG₄₅ at a 200:1 ratio, using procedures similar to those described in Example II.

In batches 1, 2, 4 and 5, 1 mg of prh-α-GAL-II was reacted with 3.98 mg bis-NHS-PEG.

In batch 3, 20.5 mg of prh-α-GAL-II was reacted with 80.7 mg bis-NHS-PEG.

The enzymatic activity of the cross-linked prh-α-GAL-II was determined as described in Example III. The results are summarized in Table 9 below.

TABLE 9 Activity results of cross-linked plant recombinant human α-GAL-II from different batches Expected α-GAL Measured α-GAL Batch no. activity [mg/mL] activity [mg/mL] 1 1.25 1.38 2 1.25 1.23 3 1.43 1.4 4 1.25 0.85 5 1.25 1.11

As shown in Table 9, the measured activity was close to the expected activity in all 5 batches. In 4 of the 5 batches, the measured activity differed from the expected activity by about 10% or less.

These results indicate that the obtained activity of the cross-linked prh-α-GAL-II is relatively predictable and reproducible.

The stability of the cross-linked prh-α-GAL-II under lysosomal conditions and in human plasma was determined as described hereinabove.

As shown in FIGS. 40A and 40B, the stability of the cross-linked prh-α-GAL-II exhibited good reproducibility under both simulated lysosomal conditions and in human plasma.

The cross-linking was also analyzed by SDS-PAGE analysis, IEF (isoelectric focusing) analysis, and MALDI-TOF mass spectrometry, as described hereinabove. Non-cross-linked prh-α-GAL-II was analyzed for comparison.

As shown in FIG. 41, the cross-linked prh-α-GAL-II from the different batches exhibited the same degree of covalent dimerization under SDS-PAGE analysis.

As shown in FIG. 42, the cross-linked prh-α-GAL-II from the different batches exhibited the same isoelectric points under IEF analysis.

As shown in FIGS. 43A-43F, the cross-linked prh-α-GAL-II from batches 1-5 (FIGS. 43B-43F, respectively) all exhibited an increase of approximately 20-21 KDa in the dimer form, as compared to the non-cross-linked prh-α-GAL-II (FIG. 43A). Such an increase corresponds to about 10 PEG molecules per α-GAL dimer. As further shown in FIGS. 43B-43F, the cross-linked prh-α-GAL-II from the different batches exhibited similar proportions of monomer vs. dimer.

These results further indicate that good reproducibility in cross-linking of α-GAL.

The kinetic parameters of the cross-linked prh-α-GAL-II were determined using a pNP-G substrate and Michaelis-Menten analysis, in order to examine the reproducibility of enzymatic activity. The measurements were performed in a solution of 20 mM citrate, 30 mM sodium phosphate, 0.1% bovine serum albumin and 0.67% ethanol, at a pH of 4.6. The kinetic parameters were calculated using protein content values based on optical density at 280 nm.

As shown in FIG. 44, the cross-linked prh-α-GAL-II from the different batches exhibited similar profiles of catalytic velocity vs. substrate concentration.

As shown in Table 10 below, the cross-linked prh-α-GAL-II from the different batches exhibited good reproducibility of the V_(max) and k_(cat) parameters. The K_(m) parameter varied more between batches, although this may be an artifact of the protein quantification.

The above results indicate good reproducibility in the enzymatic properties of cross-linked α-GAL.

TABLE 10 Michaelis-Menten parameters of plant recombinant human α-GAL II cross-linked with bis-NHS-PEG₄₅ in different batches K_(m) V_(max) k_(cat) k_(cat)/K_(m) Batch no. (μM) (μM/min) (sec⁻¹) (sec⁻¹ μM⁻¹) 1 4939 3.87 61.92 0.0125 2 2215 3.30 52.86 0.0239 3 4470 3.95 63.12 0.0141 4 3285 3.72 59.53 0.018 5 2243 3.91 62.60 0.028

Although the invention has been described in conjunction with specific embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, it is intended to embrace all such alternatives, modifications and variations that fall within the spirit and broad scope of the appended claims.

All publications, patents and patent applications mentioned in this specification are herein incorporated in their entirety by reference into the specification, to the same extent as if each individual publication, patent or patent application was specifically and individually indicated to be incorporated herein by reference. In addition, citation or identification of any reference in this application shall not be construed as an admission that such reference is available as prior art to the present invention. To the extent that section headings are used, they should not be construed as necessarily limiting. 

1-20. (canceled)
 21. A stabilized form of α-galactosidase comprising at least two native α-galactosidase monomers covalently linked to one another via a linking moiety.
 22. The stabilized form of α-galactosidase of claim 21 comprising two native α-galactosidase monomers covalently linked to one another via a linking moiety.
 23. The stabilized form of α-galactosidase of claim 21, wherein the linking moiety is a non-peptidic moiety.
 24. The stabilized form of α-galactosidase of claim 23, wherein the linking moiety comprises poly(alkylene glycol) and at least two functional groups, wherein each functional group forms a covalent bond with one of the native α-galactosidase monomers.
 25. The stabilized form of α-galactosidase of claim 24, wherein the poly(alkylene glycol) comprises ethylene glycol and/or propylene glycol units linked together.
 26. The stabilized form of α-galactosidase of claim 24, wherein the linking moiety has the following general formula: —X₁—(CR₁R₂—CR₃R₄—Y)n-X₂— wherein: each of X₁ and X₂ is a functional group that forms a covalent bond with at least one α-galactosidase monomer; C is a carbon atom; Y is an oxygen atom, a sulfur atom or NR₅, wherein NR₅ is a nitrogen atom attached to R₅; n is an integer from 5 to 150; and each of R₁, R₂, R₃, R₄ and R₅ is independently selected from the group consisting of hydrogen, alkyl, cycloalkyl, alkenyl, alkynyl, alkoxy, hydroxy, oxo, thiol and thioalkoxy.
 27. The stabilized form of α-galactosidase of claim 26, wherein at least one of said functional groups forms an amide bond with an α-galactosidase monomer.
 28. The stabilized form of α-galactosidase of claim 26, wherein said linking moiety is at least 20 atoms long.
 29. The stabilized form of α-galactosidase of claim 26, wherein n is at least
 25. 30. The stabilized form of α-galactosidase of claim 26, wherein n is an integer from 40 to
 70. 31. The stabilized form of α-galactosidase of claim 26, wherein each of R₁, R₂, R₃, R₄ and R₅ is independently selected from the group consisting of hydrogen and oxo.
 32. The stabilized form of α-galactosidase of claim 21, featuring a characteristic selected from the group consisting of: (a) an α-galactosidase activity upon subjecting the stabilized form of α-galactosidase to human plasma conditions for one hour which is at least 10% higher than an activity of naturally occurring α-galactosidase upon subjecting said naturally occurring α-galactosidase to said human plasma conditions for one hour; (b) an α-galactosidase activity which decreases upon subjecting the stabilized form of α-galactosidase to human plasma conditions for one hour by a percentage which is at least 10% less than the percentage by which an activity of naturally occurring α-galactosidase decreases upon subjecting said naturally occurring α-galactosidase to said human plasma conditions for one hour; (c) an α-galactosidase activity which remains in a range of 50% to 150% of the initial activity upon subjecting the stabilized form of α-galactosidase to human plasma conditions for one hour; (d) an α-galactosidase activity upon subjecting the stabilized form of α-galactosidase to lysosomal conditions for one week, which is at least 10% higher than an activity of naturally occurring α-galactosidase upon subjecting said naturally occurring α-galactosidase to said lysosomal conditions for one week; (e) an α-galactosidase activity which decreases upon subjecting the stabilized form of α-galactosidase to lysosomal conditions for one day by a percentage which is at least 10% less than the percentage by which an activity of naturally occurring α-galactosidase decreases upon subjecting said naturally occurring α-galactosidase to said lysosomal conditions for one day; (f) an α-galactosidase activity which remains in a range of 50% to 150% of the initial activity upon subjecting the stabilized form of α-galactosidase to lysosomal conditions for one day; (g) an α-galactosidase activity immediately upon subjecting the stabilized form of α-galactosidase to lysosomal conditions, which is at least 10% higher than an activity of naturally occurring α-galactosidase immediately upon subjecting said naturally occurring α-galactosidase to said lysosomal conditions; (h) an α-galactosidase activity immediately upon subjecting the stabilized form of α-galactosidase to an aqueous solution having a pH of 7 and a temperature of 37° C., which is at least 10% higher than an activity of naturally occurring α-galactosidase immediately upon subjecting said naturally occurring α-galactosidase to said aqueous solution having a pH of 7 and a temperature of 37° C.; and (i) a circulating half-life in human plasma which is higher than a circulating half-life of naturally occurring α-galactosidase.
 33. The stabilized form of α-galactosidase of claim 21, wherein said α-galactosidase is a human α-galactosidase.
 34. The stabilized form of α-galactosidase of claim 33, wherein said human α-galactosidase is selected from the group consisting of agalsidase alpha and agalsidase beta.
 35. The stabilized form of α-galactosidase of claim 21, wherein said α-galactosidase is a plant recombinant α-galactosidase.
 36. A pharmaceutical composition comprising the stabilized form of α-galactosidase of claim 21 and a pharmaceutically acceptable carrier.
 37. A method of treating Fabry disease in a subject in need thereof, said method comprising administering to said subject the stabilized form of α-galactosidase of claim 21, such that said Fabry disease in said subject is treated.
 38. The method of claim 37, wherein said administering is by an intravenous infusion.
 39. A process of preparing the stabilized form of α-galactosidase of claim 21, said process comprising reacting α-galactosidase comprising at least two native α-galactosidase monomers with a cross-linking agent, wherein said cross-linking agent comprises a linking moiety and at least two reactive groups.
 40. The process of claim 39, wherein said reactive groups comprise a leaving group. 